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https://github.com/bevyengine/bevy
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186 commits
| Author | SHA1 | Message | Date | |
|---|---|---|---|---|
hshrimp
|
35d10866b8
|
Rename init_component & friends (#15454)
# Objective - Fixes #15451 ## Migration Guide - `World::init_component` has been renamed to `register_component`. - `World::init_component_with_descriptor` has been renamed to `register_component_with_descriptor`. - `World::init_bundle` has been renamed to `register_bundle`. - `Components::init_component` has been renamed to `register_component`. - `Components::init_component_with_descriptor` has been renamed to `register_component_with_descriptor`. - `Components::init_resource` has been renamed to `register_resource`. - `Components::init_non_send` had been renamed to `register_non_send`. |
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Clar Fon
|
efda7f3f9c
|
Simpler lint fixes: makes ci lints work but disables a lint for now (#15376)
Takes the first two commits from #15375 and adds suggestions from this comment: https://github.com/bevyengine/bevy/pull/15375#issuecomment-2366968300 See #15375 for more reasoning/motivation. ## Rebasing (rerunning) ```rust git switch simpler-lint-fixes git reset --hard main cargo fmt --all -- --unstable-features --config normalize_comments=true,imports_granularity=Crate cargo fmt --all git add --update git commit --message "rustfmt" cargo clippy --workspace --all-targets --all-features --fix cargo fmt --all -- --unstable-features --config normalize_comments=true,imports_granularity=Crate cargo fmt --all git add --update git commit --message "clippy" git cherry-pick e6c0b94f6795222310fb812fa5c4512661fc7887 ``` |
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Christian Hughes
|
c7ec456e50
|
Support systems that take references as input (#15184)
# Objective - Fixes #14924 - Closes #9584 ## Solution - We introduce a new trait, `SystemInput`, that serves as a type function from the `'static` form of the input, to its lifetime'd version, similarly to `SystemParam` or `WorldQuery`. - System functions now take the lifetime'd wrapped version, `SystemInput::Param<'_>`, which prevents the issue presented in #14924 (i.e. `InRef<T>`). - Functions for running systems now take the lifetime'd unwrapped version, `SystemInput::Inner<'_>` (i.e. `&T`). - Due to the above change, system piping had to be re-implemented as a standalone type, rather than `CombinatorSystem` as it was previously. - Removes the `Trigger<'static, E, B>` transmute in observer runner code. ## Testing - All current tests pass. - Added additional tests and doc-tests. --- ## Showcase ```rust let mut world = World::new(); let mut value = 2; // Currently possible: fn square(In(input): In<usize>) -> usize { input * input } value = world.run_system_once_with(value, square); // Now possible: fn square_mut(InMut(input): InMut<usize>) { *input *= *input; } world.run_system_once_with(&mut value, square_mut); // Or: fn square_ref(InRef(input): InRef<usize>) -> usize { *input * *input } value = world.run_system_once_with(&value, square_ref); ``` ## Migration Guide - All current explicit usages of the following types must be changed in the way specified: - `SystemId<I, O>` to `SystemId<In<I>, O>` - `System<In = T>` to `System<In = In<T>>` - `IntoSystem<I, O, M>` to `IntoSystem<In<I>, O, M>` - `Condition<M, T>` to `Condition<M, In<T>>` - `In<Trigger<E, B>>` is no longer a valid input parameter type. Use `Trigger<E, B>` directly, instead. --------- Co-authored-by: Giacomo Stevanato <giaco.stevanato@gmail.com> |
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Adam
|
9bda913e36
|
Remove redundent information and optimize dynamic allocations in Table (#12929)
# Objective - fix #12853 - Make `Table::allocate` faster ## Solution The PR consists of multiple steps: 1) For the component data: create a new data-structure that's similar to `BlobVec` but doesn't store `len` & `capacity` inside of it: "BlobArray" (name suggestions welcome) 2) For the `Tick` data: create a new data-structure that's similar to `ThinSlicePtr` but supports dynamic reallocation: "ThinArrayPtr" (name suggestions welcome) 3) Create a new data-structure that's very similar to `Column` that doesn't store `len` & `capacity` inside of it: "ThinColumn" 4) Adjust the `Table` implementation to use `ThinColumn` instead of `Column` The result is that only one set of `len` & `capacity` is stored in `Table`, in `Table::entities` ### Notes Regarding Performance Apart from shaving off some excess memory in `Table`, the changes have also brought noteworthy performance improvements: The previous implementation relied on `Vec::reserve` & `BlobVec::reserve`, but that redundantly repeated the same if statement (`capacity` == `len`). Now that check could be made at the `Table` level because the capacity and length of all the columns are synchronized; saving N branches per allocation. The result is a respectable performance improvement per every `Table::reserve` (and subsequently `Table::allocate`) call. I'm hesitant to give exact numbers because I don't have a lot of experience in profiling and benchmarking, but these are the results I got so far: *`add_remove_big/table` benchmark after the implementation:*  *`add_remove_big/table` benchmark in main branch (measured in comparison to the implementation):*  *`add_remove_very_big/table` benchmark after the implementation:*  *`add_remove_very_big/table` benchmark in main branch (measured in comparison to the implementation):*  cc @james7132 to verify --- ## Changelog - New data-structure that's similar to `BlobVec` but doesn't store `len` & `capacity` inside of it: `BlobArray` - New data-structure that's similar to `ThinSlicePtr` but supports dynamic allocation:`ThinArrayPtr` - New data-structure that's very similar to `Column` that doesn't store `len` & `capacity` inside of it: `ThinColumn` - Adjust the `Table` implementation to use `ThinColumn` instead of `Column` - New benchmark: `add_remove_very_big` to benchmark the performance of spawning a lot of entities with a lot of components (15) each ## Migration Guide `Table` now uses `ThinColumn` instead of `Column`. That means that methods that previously returned `Column`, will now return `ThinColumn` instead. `ThinColumn` has a much more limited and low-level API, but you can still achieve the same things in `ThinColumn` as you did in `Column`. For example, instead of calling `Column::get_added_tick`, you'd call `ThinColumn::get_added_ticks_slice` and index it to get the specific added tick. --------- Co-authored-by: James Liu <contact@jamessliu.com> |
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BD103
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6ec6a55645
|
Unify crate-level preludes (#15080)
# Objective
- Crate-level prelude modules, such as `bevy_ecs::prelude`, are plagued
with inconsistency! Let's fix it!
## Solution
Format all preludes based on the following rules:
1. All preludes should have brief documentation in the format of:
> The _name_ prelude.
>
> This includes the most common types in this crate, re-exported for
your convenience.
2. All documentation should be outer, not inner. (`///` instead of
`//!`.)
3. No prelude modules should be annotated with `#[doc(hidden)]`. (Items
within them may, though I'm not sure why this was done.)
## Testing
- I manually searched for the term `mod prelude` and updated all
occurrences by hand. 🫠
---------
Co-authored-by: Gino Valente <49806985+MrGVSV@users.noreply.github.com>
|
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Zachary Harrold
|
bc13161416
|
Migrated NonZero* to NonZero<*> (#14978)
# Objective - Fixes #14974 ## Solution - Replace all* instances of `NonZero*` with `NonZero<*>` ## Testing - CI passed locally. --- ## Notes Within the `bevy_reflect` implementations for `std` types, `impl_reflect_value!()` will continue to use the type aliases instead, as it inappropriately parses the concrete type parameter as a generic argument. If the `ZeroablePrimitive` trait was stable, or the macro could be modified to accept a finite list of types, then we could fully migrate. |
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Carter Anderson
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9cdb915809
|
Required Components (#14791)
## Introduction This is the first step in my [Next Generation Scene / UI Proposal](https://github.com/bevyengine/bevy/discussions/14437). Fixes https://github.com/bevyengine/bevy/issues/7272 #14800. Bevy's current Bundles as the "unit of construction" hamstring the UI user experience and have been a pain point in the Bevy ecosystem generally when composing scenes: * They are an additional _object defining_ concept, which must be learned separately from components. Notably, Bundles _are not present at runtime_, which is confusing and limiting. * They can completely erase the _defining component_ during Bundle init. For example, `ButtonBundle { style: Style::default(), ..default() }` _makes no mention_ of the `Button` component symbol, which is what makes the Entity a "button"! * They are not capable of representing "dependency inheritance" without completely non-viable / ergonomically crushing nested bundles. This limitation is especially painful in UI scenarios, but it applies to everything across the board. * They introduce a bunch of additional nesting when defining scenes, making them ugly to look at * They introduce component name "stutter": `SomeBundle { component_name: ComponentName::new() }` * They require copious sprinklings of `..default()` when spawning them in Rust code, due to the additional layer of nesting **Required Components** solve this by allowing you to define which components a given component needs, and how to construct those components when they aren't explicitly provided. This is what a `ButtonBundle` looks like with Bundles (the current approach): ```rust #[derive(Component, Default)] struct Button; #[derive(Bundle, Default)] struct ButtonBundle { pub button: Button, pub node: Node, pub style: Style, pub interaction: Interaction, pub focus_policy: FocusPolicy, pub border_color: BorderColor, pub border_radius: BorderRadius, pub image: UiImage, pub transform: Transform, pub global_transform: GlobalTransform, pub visibility: Visibility, pub inherited_visibility: InheritedVisibility, pub view_visibility: ViewVisibility, pub z_index: ZIndex, } commands.spawn(ButtonBundle { style: Style { width: Val::Px(100.0), height: Val::Px(50.0), ..default() }, focus_policy: FocusPolicy::Block, ..default() }) ``` And this is what it looks like with Required Components: ```rust #[derive(Component)] #[require(Node, UiImage)] struct Button; commands.spawn(( Button, Style { width: Val::Px(100.0), height: Val::Px(50.0), ..default() }, FocusPolicy::Block, )); ``` With Required Components, we mention only the most relevant components. Every component required by `Node` (ex: `Style`, `FocusPolicy`, etc) is automatically brought in! ### Efficiency 1. At insertion/spawn time, Required Components (including recursive required components) are initialized and inserted _as if they were manually inserted alongside the given components_. This means that this is maximally efficient: there are no archetype or table moves. 2. Required components are only initialized and inserted if they were not manually provided by the developer. For the code example in the previous section, because `Style` and `FocusPolicy` are inserted manually, they _will not_ be initialized and inserted as part of the required components system. Efficient! 3. The "missing required components _and_ constructors needed for an insertion" are cached in the "archetype graph edge", meaning they aren't computed per-insertion. When a component is inserted, the "missing required components" list is iterated (and that graph edge (AddBundle) is actually already looked up for us during insertion, because we need that for "normal" insert logic too). ### IDE Integration The `#[require(SomeComponent)]` macro has been written in such a way that Rust Analyzer can provide type-inspection-on-hover and `F12` / go-to-definition for required components. ### Custom Constructors The `require` syntax expects a `Default` constructor by default, but it can be overridden with a custom constructor: ```rust #[derive(Component)] #[require( Node, Style(button_style), UiImage )] struct Button; fn button_style() -> Style { Style { width: Val::Px(100.0), ..default() } } ``` ### Multiple Inheritance You may have noticed by now that this behaves a bit like "multiple inheritance". One of the problems that this presents is that it is possible to have duplicate requires for a given type at different levels of the inheritance tree: ```rust #[derive(Component) struct X(usize); #[derive(Component)] #[require(X(x1)) struct Y; fn x1() -> X { X(1) } #[derive(Component)] #[require( Y, X(x2), )] struct Z; fn x2() -> X { X(2) } // What version of X is inserted for Z? commands.spawn(Z); ``` This is allowed (and encouraged), although this doesn't appear to occur much in practice. First: only one version of `X` is initialized and inserted for `Z`. In the case above, I think we can all probably agree that it makes the most sense to use the `x2` constructor for `X`, because `Y`'s `x1` constructor exists "beneath" `Z` in the inheritance hierarchy; `Z`'s constructor is "more specific". The algorithm is simple and predictable: 1. Use all of the constructors (including default constructors) directly defined in the spawned component's require list 2. In the order the requires are defined in `#[require()]`, recursively visit the require list of each of the components in the list (this is a depth Depth First Search). When a constructor is found, it will only be used if one has not already been found. From a user perspective, just think about this as the following: 1. Specifying a required component constructor for `Foo` directly on a spawned component `Bar` will result in that constructor being used (and overriding existing constructors lower in the inheritance tree). This is the classic "inheritance override" behavior people expect. 2. For cases where "multiple inheritance" results in constructor clashes, Components should be listed in "importance order". List a component earlier in the requirement list to initialize its inheritance tree earlier. Required Components _does_ generally result in a model where component values are decoupled from each other at construction time. Notably, some existing Bundle patterns use bundle constructors to initialize multiple components with shared state. I think (in general) moving away from this is necessary: 1. It allows Required Components (and the Scene system more generally) to operate according to simple rules 2. The "do arbitrary init value sharing in Bundle constructors" approach _already_ causes data consistency problems, and those problems would be exacerbated in the context of a Scene/UI system. For cases where shared state is truly necessary, I think we are better served by observers / hooks. 3. If a situation _truly_ needs shared state constructors (which should be rare / generally discouraged), Bundles are still there if they are needed. ## Next Steps * **Require Construct-ed Components**: I have already implemented this (as defined in the [Next Generation Scene / UI Proposal](https://github.com/bevyengine/bevy/discussions/14437). However I've removed `Construct` support from this PR, as that has not landed yet. Adding this back in requires relatively minimal changes to the current impl, and can be done as part of a future Construct pr. * **Port Built-in Bundles to Required Components**: This isn't something we should do right away. It will require rethinking our public interfaces, which IMO should be done holistically after the rest of Next Generation Scene / UI lands. I think we should merge this PR first and let people experiment _inside their own code with their own Components_ while we wait for the rest of the new scene system to land. * **_Consider_ Automatic Required Component Removal**: We should evaluate _if_ automatic Required Component removal should be done. Ex: if all components that explicitly require a component are removed, automatically remove that component. This issue has been explicitly deferred in this PR, as I consider the insertion behavior to be desirable on its own (and viable on its own). I am also doubtful that we can find a design that has behavior we actually want. Aka: can we _really_ distinguish between a component that is "only there because it was automatically inserted" and "a component that was necessary / should be kept". See my [discussion response here](https://github.com/bevyengine/bevy/discussions/14437#discussioncomment-10268668) for more details. --------- Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com> Co-authored-by: BD103 <59022059+BD103@users.noreply.github.com> Co-authored-by: Pascal Hertleif <killercup@gmail.com> |
||
Ben Frankel
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6da2305e49
|
Add Command and co. to prelude (#14751)
# Objective Make it easier to write and work with custom `Command`s and `EntityCommand`s. See https://discord.com/channels/691052431525675048/692572690833473578/1273030340235100214 for (brief) context. ## Solution Re-export `Command`, `EntityCommand`, and `EntityCommands` in the `bevy_ecs::prelude`, where `Commands` is already re-exported. |
||
Tau Gärtli
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aab1f8e435
|
Use #[doc(fake_variadic)] to improve docs readability (#14703)
# Objective - Fixes #14697 ## Solution This PR modifies the existing `all_tuples!` macro to optionally accept a `#[doc(fake_variadic)]` attribute in its input. If the attribute is present, each invocation of the impl macro gets the correct attributes (i.e. the first impl receives `#[doc(fake_variadic)]` while the other impls are hidden using `#[doc(hidden)]`. Impls for the empty tuple (unit type) are left untouched (that's what the [standard library](https://doc.rust-lang.org/std/cmp/trait.PartialEq.html#impl-PartialEq-for-()) and [serde](https://docs.rs/serde/latest/serde/trait.Serialize.html#impl-Serialize-for-()) do). To work around https://github.com/rust-lang/cargo/issues/8811 and to get impls on re-exports to correctly show up as variadic, `--cfg docsrs_dep` is passed when building the docs for the toplevel `bevy` crate. `#[doc(fake_variadic)]` only works on tuples and fn pointers, so impls for structs like `AnyOf<(T1, T2, ..., Tn)>` are unchanged. ## Testing I built the docs locally using `RUSTDOCFLAGS='--cfg docsrs' RUSTFLAGS='--cfg docsrs_dep' cargo +nightly doc --no-deps --workspace` and checked the documentation page of a trait both in its original crate and the re-exported version in `bevy`. The description should correctly mention for how many tuple items the trait is implemented. I added `rustc-args` for docs.rs to the `bevy` crate, I hope there aren't any other notable crates that re-export `#[doc(fake_variadic)]` traits. --- ## Showcase `bevy_ecs::query::QueryData`: <img width="1015" alt="Screenshot 2024-08-12 at 16 41 28" src="https://github.com/user-attachments/assets/d40136ed-6731-475f-91a0-9df255cd24e3"> `bevy::ecs::query::QueryData` (re-export): <img width="1005" alt="Screenshot 2024-08-12 at 16 42 57" src="https://github.com/user-attachments/assets/71d44cf0-0ab0-48b0-9a51-5ce332594e12"> ## Original Description <details> Resolves #14697 Submitting as a draft for now, very WIP. Unfortunately, the docs don't show the variadics nicely when looking at reexported items. For example: `bevy_ecs::bundle::Bundle` correctly shows the variadic impl:  while `bevy::ecs::bundle::Bundle` (the reexport) shows all the impls (not good):  Built using `RUSTDOCFLAGS='--cfg docsrs' cargo +nightly doc --workspace --no-deps` (`--no-deps` because of wgpu-core). Maybe I missed something or this is a limitation in the *totally not private* `#[doc(fake_variadic)]` thingy. In any case I desperately need some sleep now :)) </details> |
||
Chris Russell
|
d4ec80d5d2
|
Support more kinds of system params in buildable systems. (#14050)
# Objective
Support more kinds of system params in buildable systems, such as a
`ParamSet` or `Vec` containing buildable params or tuples of buildable
params.
## Solution
Replace the `BuildableSystemParam` trait with `SystemParamBuilder` to
make it easier to compose builders. Provide implementations for existing
buildable params, plus tuples, `ParamSet`, and `Vec`.
## Examples
```rust
// ParamSet of tuple:
let system = (ParamSetBuilder((
QueryParamBuilder::new(|builder| { builder.with::<B>(); }),
QueryParamBuilder::new(|builder| { builder.with::<C>(); }),
)),)
.build_state(&mut world)
.build_system(|mut params: ParamSet<(Query<&mut A>, Query<&mut A>)>| {
params.p0().iter().count() + params.p1().iter().count()
});
// ParamSet of Vec:
let system = (ParamSetBuilder(vec![
QueryParamBuilder::new_box(|builder| { builder.with::<B>(); }),
QueryParamBuilder::new_box(|builder| { builder.with::<C>(); }),
]),)
.build_state(&mut world)
.build_system(|mut params: ParamSet<Vec<Query<&mut A>>>| {
let mut count = 0;
params.for_each(|mut query| count += query.iter_mut().count());
count
});
```
## Migration Guide
The API for `SystemBuilder` has changed. Instead of constructing a
builder with a world and then adding params, you first create a tuple of
param builders and then supply the world.
```rust
// Before
let system = SystemBuilder::<()>::new(&mut world)
.local::<u64>()
.builder::<Local<u64>>(|x| *x = 10)
.builder::<Query<&A>>(|builder| { builder.with::<B>(); })
.build(system);
// After
let system = (
ParamBuilder,
LocalBuilder(10),
QueryParamBuilder::new(|builder| { builder.with::<B>(); }),
)
.build_state(&mut world)
.build_system(system);
```
## Possible Future Work
Here are a few possible follow-up changes. I coded them up to prove that
this API can support them, but they aren't necessary for this PR.
* chescock/bevy#1
* chescock/bevy#2
* chescock/bevy#3
|
||
Periwink
|
e85c072372
|
Fix soudness issue with Conflicts involving read_all and write_all (#14579)
# Objective - Fixes https://github.com/bevyengine/bevy/issues/14575 - There is a soundness issue because we use `conflicts()` to check for system ambiguities + soundness issues. However since the current conflicts is a `Vec<T>`, we cannot express conflicts where there is no specific `ComponentId` at fault. For example `q1: Query<EntityMut>, q2: Query<EntityMut>` There was a TODO to handle the `write_all` case but it was never resolved ## Solution - Introduce an `AccessConflict` enum that is either a list of specific ids that are conflicting or `All` if all component ids are conflicting ## Testing - Introduced a new unit test to check for the `EntityMut` case ## Migration guide The `get_conflicts` method of `Access` now returns an `AccessConflict` enum instead of simply a `Vec` of `ComponentId`s that are causing the access conflict. This can be useful in cases where there are no particular `ComponentId`s conflicting, but instead **all** of them are; for example `fn system(q1: Query<EntityMut>, q2: Query<EntityRef>)` |
||
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Periwink
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3a664b052d
|
Separate component and resource access (#14561)
# Objective - Fixes https://github.com/bevyengine/bevy/issues/13139 - Fixes https://github.com/bevyengine/bevy/issues/7255 - Separates component from resource access so that we can correctly handles edge cases like the issue above - Inspired from https://github.com/bevyengine/bevy/pull/14472 ## Solution - Update access to have `component` fields and `resource` fields ## Testing - Added some unit tests |
||
Gino Valente
|
df61117850
|
bevy_reflect: Function registry (#14098)
# Objective #13152 added support for reflecting functions. Now, we need a way to register those functions such that they may be accessed anywhere within the ECS. ## Solution Added a `FunctionRegistry` type similar to `TypeRegistry`. This allows a function to be registered and retrieved by name. ```rust fn foo() -> i32 { 123 } let mut registry = FunctionRegistry::default(); registry.register("my_function", foo); let function = registry.get_mut("my_function").unwrap(); let value = function.call(ArgList::new()).unwrap().unwrap_owned(); assert_eq!(value.downcast_ref::<i32>(), Some(&123)); ``` Additionally, I added an `AppFunctionRegistry` resource which wraps a `FunctionRegistryArc`. Functions can be registered into this resource using `App::register_function` or by getting a mutable reference to the resource itself. ### Limitations #### `Send + Sync` In order to get this registry to work across threads, it needs to be `Send + Sync`. This means that `DynamicFunction` needs to be `Send + Sync`, which means that its internal function also needs to be `Send + Sync`. In most cases, this won't be an issue because standard Rust functions (the type most likely to be registered) are always `Send + Sync`. Additionally, closures tend to be `Send + Sync` as well, granted they don't capture any `!Send` or `!Sync` variables. This PR adds this `Send + Sync` requirement, but as mentioned above, it hopefully shouldn't be too big of an issue. #### Closures Unfortunately, closures can't be registered yet. This will likely be explored and added in a followup PR. ### Future Work Besides addressing the limitations listed above, another thing we could look into is improving the lookup of registered functions. One aspect is in the performance of hashing strings. The other is in the developer experience of having to call `std::any::type_name_of_val` to get the name of their function (assuming they didn't give it a custom name). ## Testing You can run the tests locally with: ``` cargo test --package bevy_reflect ``` --- ## Changelog - Added `FunctionRegistry` - Added `AppFunctionRegistry` (a `Resource` available from `bevy_ecs`) - Added `FunctionRegistryArc` - Added `FunctionRegistrationError` - Added `reflect_functions` feature to `bevy_ecs` and `bevy_app` - `FunctionInfo` is no longer `Default` - `DynamicFunction` now requires its wrapped function be `Send + Sync` ## Internal Migration Guide > [!important] > Function reflection was introduced as part of the 0.15 dev cycle. This migration guide was written for developers relying on `main` during this cycle, and is not a breaking change coming from 0.14. `DynamicFunction` (both those created manually and those created with `IntoFunction`), now require `Send + Sync`. All standard Rust functions should meet that requirement. Closures, on the other hand, may not if they capture any `!Send` or `!Sync` variables from its environment. |
||
|
Periwink
|
ec4cf024f8
|
Add a ComponentIndex and update QueryState creation/update to use it (#13460)
# Objective
To implement relations we will need to add a `ComponentIndex`, which is
a map from a Component to the list of archetypes that contain this
component.
One of the reasons is that with fragmenting relations the number of
archetypes will explode, so it will become inefficient to create and
update the query caches by iterating through the list of all archetypes.
In this PR, we introduce the `ComponentIndex`, and we update the
`QueryState` to make use of it:
- if a query has at least 1 required component (i.e. something other
than `()`, `Entity` or `Option<>`, etc.): for each of the required
components we find the list of archetypes that contain it (using the
ComponentIndex). Then, we select the smallest list among these. This
gives a small subset of archetypes to iterate through compared with
iterating through all new archetypes
- if it doesn't, then we keep using the current approach of iterating
through all new archetypes
# Implementation
- This breaks query iteration order, in the sense that we are not
guaranteed anymore to return results in the order in which the
archetypes were created. I think this should be fine because this wasn't
an explicit bevy guarantee so users should not be relying on this. I
updated a bunch of unit tests that were failing because of this.
- I had an issue with the borrow checker because iterating the list of
potential archetypes requires access to `&state.component_access`, which
was conflicting with the calls to
```
if state.new_archetype_internal(archetype) {
state.update_archetype_component_access(archetype, access);
}
```
which need a mutable access to the state.
The solution I chose was to introduce a `QueryStateView` which is a
temporary view into the `QueryState` which enables a "split-borrows"
kind of approach. It is described in detail in this blog post:
https://smallcultfollowing.com/babysteps/blog/2018/11/01/after-nll-interprocedural-conflicts/
# Test
The unit tests pass.
Benchmark results:
```
❯ critcmp main pr
group main pr
----- ---- --
iter_fragmented/base 1.00 342.2±25.45ns ? ?/sec 1.02 347.5±16.24ns ? ?/sec
iter_fragmented/foreach 1.04 165.4±11.29ns ? ?/sec 1.00 159.5±4.27ns ? ?/sec
iter_fragmented/foreach_wide 1.03 3.3±0.04µs ? ?/sec 1.00 3.2±0.06µs ? ?/sec
iter_fragmented/wide 1.03 3.1±0.06µs ? ?/sec 1.00 3.0±0.08µs ? ?/sec
iter_fragmented_sparse/base 1.00 6.5±0.14ns ? ?/sec 1.02 6.6±0.08ns ? ?/sec
iter_fragmented_sparse/foreach 1.00 6.3±0.08ns ? ?/sec 1.04 6.6±0.08ns ? ?/sec
iter_fragmented_sparse/foreach_wide 1.00 43.8±0.15ns ? ?/sec 1.02 44.6±0.53ns ? ?/sec
iter_fragmented_sparse/wide 1.00 29.8±0.44ns ? ?/sec 1.00 29.8±0.26ns ? ?/sec
iter_simple/base 1.00 8.2±0.10µs ? ?/sec 1.00 8.2±0.09µs ? ?/sec
iter_simple/foreach 1.00 3.8±0.02µs ? ?/sec 1.02 3.9±0.03µs ? ?/sec
iter_simple/foreach_sparse_set 1.00 19.0±0.26µs ? ?/sec 1.01 19.3±0.16µs ? ?/sec
iter_simple/foreach_wide 1.00 17.8±0.24µs ? ?/sec 1.00 17.9±0.31µs ? ?/sec
iter_simple/foreach_wide_sparse_set 1.06 95.6±6.23µs ? ?/sec 1.00 90.6±0.59µs ? ?/sec
iter_simple/sparse_set 1.00 19.3±1.63µs ? ?/sec 1.01 19.5±0.29µs ? ?/sec
iter_simple/system 1.00 8.1±0.10µs ? ?/sec 1.00 8.1±0.09µs ? ?/sec
iter_simple/wide 1.05 37.7±2.53µs ? ?/sec 1.00 35.8±0.57µs ? ?/sec
iter_simple/wide_sparse_set 1.00 95.7±1.62µs ? ?/sec 1.00 95.9±0.76µs ? ?/sec
par_iter_simple/with_0_fragment 1.04 35.0±2.51µs ? ?/sec 1.00 33.7±0.49µs ? ?/sec
par_iter_simple/with_1000_fragment 1.00 50.4±2.52µs ? ?/sec 1.01 51.0±3.84µs ? ?/sec
par_iter_simple/with_100_fragment 1.02 40.3±2.23µs ? ?/sec 1.00 39.5±1.32µs ? ?/sec
par_iter_simple/with_10_fragment 1.14 38.8±7.79µs ? ?/sec 1.00 34.0±0.78µs ? ?/sec
```
|
||
|
BD103
|
399219a2c7
|
Fix rust beta lints (#14537)
# Objective - Fixes #14517. ## Solution - Replace two instances of `map()` with `inspect()`. - `#[allow(dead_code)]` on `Bundle` derive macro tests. ## Testing You need to install the beta toolchain, since these lints are not stable yet. ```bash cargo +beta clippy --workspace cargo +beta test --workspace ``` |
||
Pixelstorm
|
0f7c548a4a
|
Component Lifecycle Hook & Observer Trigger for replaced values (#14212)
# Objective Fixes #14202 ## Solution Add `on_replaced` component hook and `OnReplaced` observer trigger ## Testing - Did you test these changes? If so, how? - Updated & added unit tests --- ## Changelog - Added new `on_replaced` component hook and `OnReplaced` observer trigger for performing cleanup on component values when they are overwritten with `.insert()` |
||
Miles Silberling-Cook
|
ed2b8e0f35
|
Minimal Bubbling Observers (#13991)
# Objective
Add basic bubbling to observers, modeled off `bevy_eventlistener`.
## Solution
- Introduce a new `Traversal` trait for components which point to other
entities.
- Provide a default `TraverseNone: Traversal` component which cannot be
constructed.
- Implement `Traversal` for `Parent`.
- The `Event` trait now has an associated `Traversal` which defaults to
`TraverseNone`.
- Added a field `bubbling: &mut bool` to `Trigger` which can be used to
instruct the runner to bubble the event to the entity specified by the
event's traversal type.
- Added an associated constant `SHOULD_BUBBLE` to `Event` which
configures the default bubbling state.
- Added logic to wire this all up correctly.
Introducing the new associated information directly on `Event` (instead
of a new `BubblingEvent` trait) lets us dispatch both bubbling and
non-bubbling events through the same api.
## Testing
I have added several unit tests to cover the common bugs I identified
during development. Running the unit tests should be enough to validate
correctness. The changes effect unsafe portions of the code, but should
not change any of the safety assertions.
## Changelog
Observers can now bubble up the entity hierarchy! To create a bubbling
event, change your `Derive(Event)` to something like the following:
```rust
#[derive(Component)]
struct MyEvent;
impl Event for MyEvent {
type Traverse = Parent; // This event will propagate up from child to parent.
const AUTO_PROPAGATE: bool = true; // This event will propagate by default.
}
```
You can dispatch a bubbling event using the normal
`world.trigger_targets(MyEvent, entity)`.
Halting an event mid-bubble can be done using
`trigger.propagate(false)`. Events with `AUTO_PROPAGATE = false` will
not propagate by default, but you can enable it using
`trigger.propagate(true)`.
If there are multiple observers attached to a target, they will all be
triggered by bubbling. They all share a bubbling state, which can be
accessed mutably using `trigger.propagation_mut()` (`trigger.propagate`
is just sugar for this).
You can choose to implement `Traversal` for your own types, if you want
to bubble along a different structure than provided by `bevy_hierarchy`.
Implementers must be careful never to produce loops, because this will
cause bevy to hang.
## Migration Guide
+ Manual implementations of `Event` should add associated type `Traverse
= TraverseNone` and associated constant `AUTO_PROPAGATE = false`;
+ `Trigger::new` has new field `propagation: &mut Propagation` which
provides the bubbling state.
+ `ObserverRunner` now takes the same `&mut Propagation` as a final
parameter.
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
Co-authored-by: Torstein Grindvik <52322338+torsteingrindvik@users.noreply.github.com>
Co-authored-by: Carter Anderson <mcanders1@gmail.com>
|
||
Bob Gardner
|
ec1aa48fc6
|
Created an EventMutator for when you want to mutate an event before reading (#13818)
# Objective - Often in games you will want to create chains of systems that modify some event. For example, a chain of damage systems that handle a DamageEvent and modify the underlying value before the health system finally consumes the event. Right now this requires either: * Using a component added to the entity * Consuming and refiring events Neither is ideal when really all we want to do is read the events value, modify it, and write it back. ## Solution - Create an EventMutator class similar to EventReader but with ResMut<T> and iterators that return &mut so that events can be mutated. ## Testing - I replicated all the existing tests for EventReader to make sure behavior was the same (I believe) and added a number of tests specific to testing that 1) events can actually be mutated, and that 2) EventReader sees changes from EventMutator for events it hasn't already seen. ## Migration Guide Users currently using `ManualEventReader` should use `EventCursor` instead. `ManualEventReader` will be removed in Bevy 0.16. Additionally, `Events::get_reader` has been replaced by `Events::get_cursor`. Users currently directly accessing the `Events` resource for mutation should move to `EventMutator` if possible. --------- Co-authored-by: poopy <gonesbird@gmail.com> Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com> |
||
James O'Brien
|
eb3c81374a
|
Generalised ECS reactivity with Observers (#10839)
# Objective
- Provide an expressive way to register dynamic behavior in response to
ECS changes that is consistent with existing bevy types and traits as to
provide a smooth user experience.
- Provide a mechanism for immediate changes in response to events during
command application in order to facilitate improved query caching on the
path to relations.
## Solution
- A new fundamental ECS construct, the `Observer`; inspired by flec's
observers but adapted to better fit bevy's access patterns and rust's
type system.
---
## Examples
There are 3 main ways to register observers. The first is a "component
observer" that looks like this:
```rust
world.observe(|trigger: Trigger<OnAdd, Transform>, query: Query<&Transform>| {
let transform = query.get(trigger.entity()).unwrap();
});
```
The above code will spawn a new entity representing the observer that
will run it's callback whenever the `Transform` component is added to an
entity. This is a system-like function that supports dependency
injection for all the standard bevy types: `Query`, `Res`, `Commands`
etc. It also has a `Trigger` parameter that provides information about
the trigger such as the target entity, and the event being triggered.
Importantly these systems run during command application which is key
for their future use to keep ECS internals up to date. There are similar
events for `OnInsert` and `OnRemove`, and this will be expanded with
things such as `ArchetypeCreated`, `TableEmpty` etc. in follow up PRs.
Another way to register an observer is an "entity observer" that looks
like this:
```rust
world.entity_mut(entity).observe(|trigger: Trigger<Resize>| {
// ...
});
```
Entity observers run whenever an event of their type is triggered
targeting that specific entity. This type of observer will de-spawn
itself if the entity (or entities) it is observing is ever de-spawned so
as to not leave dangling observers.
Entity observers can also be spawned from deferred contexts such as
other observers, systems, or hooks using commands:
```rust
commands.entity(entity).observe(|trigger: Trigger<Resize>| {
// ...
});
```
Observers are not limited to in built event types, they can be used with
any type that implements `Event` (which has been extended to implement
Component). This means events can also carry data:
```rust
#[derive(Event)]
struct Resize { x: u32, y: u32 }
commands.entity(entity).observe(|trigger: Trigger<Resize>, query: Query<&mut Size>| {
let event = trigger.event();
// ...
});
// Will trigger the observer when commands are applied.
commands.trigger_targets(Resize { x: 10, y: 10 }, entity);
```
You can also trigger events that target more than one entity at a time:
```rust
commands.trigger_targets(Resize { x: 10, y: 10 }, [e1, e2]);
```
Additionally, Observers don't _need_ entity targets:
```rust
app.observe(|trigger: Trigger<Quit>| {
})
commands.trigger(Quit);
```
In these cases, `trigger.entity()` will be a placeholder.
Observers are actually just normal entities with an `ObserverState` and
`Observer` component! The `observe()` functions above are just shorthand
for:
```rust
world.spawn(Observer::new(|trigger: Trigger<Resize>| {});
```
This will spawn the `Observer` system and use an `on_add` hook to add
the `ObserverState` component.
Dynamic components and trigger types are also fully supported allowing
for runtime defined trigger types.
## Possible Follow-ups
1. Deprecate `RemovedComponents`, observers should fulfill all use cases
while being more flexible and performant.
2. Queries as entities: Swap queries to entities and begin using
observers listening to archetype creation triggers to keep their caches
in sync, this allows unification of `ObserverState` and `QueryState` as
well as unlocking several API improvements for `Query` and the
management of `QueryState`.
3. Trigger bubbling: For some UI use cases in particular users are
likely to want some form of bubbling for entity observers, this is
trivial to implement naively but ideally this includes an acceleration
structure to cache hierarchy traversals.
4. All kinds of other in-built trigger types.
5. Optimization; in order to not bloat the complexity of the PR I have
kept the implementation straightforward, there are several areas where
performance can be improved. The focus for this PR is to get the
behavior implemented and not incur a performance cost for users who
don't use observers.
I am leaving each of these to follow up PR's in order to keep each of
them reviewable as this already includes significant changes.
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
Co-authored-by: MiniaczQ <xnetroidpl@gmail.com>
Co-authored-by: Carter Anderson <mcanders1@gmail.com>
|
||
|
James O'Brien
|
182fe3292e
|
Implement a SystemBuilder for building SystemParams (#13123)
# Objective
- Implement a general purpose mechanism for building `SystemParam`.
- Unblock the usage of dynamic queries in regular systems.
## Solution
- Implement a `SystemBuilder` type.
## Examples
Here are some simple test cases for the builder:
```rust
fn local_system(local: Local<u64>) -> u64 {
*local
}
fn query_system(query: Query<()>) -> usize {
query.iter().count()
}
fn multi_param_system(a: Local<u64>, b: Local<u64>) -> u64 {
*a + *b + 1
}
#[test]
fn local_builder() {
let mut world = World::new();
let system = SystemBuilder::<()>::new(&mut world)
.builder::<Local<u64>>(|x| *x = 10)
.build(local_system);
let result = world.run_system_once(system);
assert_eq!(result, 10);
}
#[test]
fn query_builder() {
let mut world = World::new();
world.spawn(A);
world.spawn_empty();
let system = SystemBuilder::<()>::new(&mut world)
.builder::<Query<()>>(|query| {
query.with::<A>();
})
.build(query_system);
let result = world.run_system_once(system);
assert_eq!(result, 1);
}
#[test]
fn multi_param_builder() {
let mut world = World::new();
world.spawn(A);
world.spawn_empty();
let system = SystemBuilder::<()>::new(&mut world)
.param::<Local<u64>>()
.param::<Local<u64>>()
.build(multi_param_system);
let result = world.run_system_once(system);
assert_eq!(result, 1);
}
```
This will be expanded as this PR is iterated.
|
||
Lee-Orr
|
42ba9dfaea
|
Separate state crate (#13216)
# Objective Extracts the state mechanisms into a new crate called "bevy_state". This comes with a few goals: - state wasn't really an inherent machinery of the ecs system, and so keeping it within bevy_ecs felt forced - by mixing it in with bevy_ecs, the maintainability of our more robust state system was significantly compromised moving state into a new crate makes it easier to encapsulate as it's own feature, and easier to read and understand since it's no longer a single, massive file. ## Solution move the state-related elements from bevy_ecs to a new crate ## Testing - Did you test these changes? If so, how? all the automated tests migrated and passed, ran the pre-existing examples without changes to validate. --- ## Migration Guide Since bevy_state is now gated behind the `bevy_state` feature, projects that use state but don't use the `default-features` will need to add that feature flag. Since it is no longer part of bevy_ecs, projects that use bevy_ecs directly will need to manually pull in `bevy_state`, trigger the StateTransition schedule, and handle any of the elements that bevy_app currently sets up. --------- Co-authored-by: Kristoffer Søholm <k.soeholm@gmail.com> |
||
|
Lee-Orr
|
b8832dc862
|
Computed State & Sub States (#11426)
## Summary/Description This PR extends states to allow support for a wider variety of state types and patterns, by providing 3 distinct types of state: - Standard [`States`] can only be changed by manually setting the [`NextState<S>`] resource. These states are the baseline on which the other state types are built, and can be used on their own for many simple patterns. See the [state example](https://github.com/bevyengine/bevy/blob/latest/examples/ecs/state.rs) for a simple use case - these are the states that existed so far in Bevy. - [`SubStates`] are children of other states - they can be changed manually using [`NextState<S>`], but are removed from the [`World`] if the source states aren't in the right state. See the [sub_states example](https://github.com/lee-orr/bevy/blob/derived_state/examples/ecs/sub_states.rs) for a simple use case based on the derive macro, or read the trait docs for more complex scenarios. - [`ComputedStates`] are fully derived from other states - they provide a [`compute`](ComputedStates::compute) method that takes in the source states and returns their derived value. They are particularly useful for situations where a simplified view of the source states is necessary - such as having an `InAMenu` computed state derived from a source state that defines multiple distinct menus. See the [computed state example](https://github.com/lee-orr/bevy/blob/derived_state/examples/ecs/computed_states.rscomputed_states.rs) to see a sampling of uses for these states. # Objective This PR is another attempt at allowing Bevy to better handle complex state objects in a manner that doesn't rely on strict equality. While my previous attempts (https://github.com/bevyengine/bevy/pull/10088 and https://github.com/bevyengine/bevy/pull/9957) relied on complex matching capacities at the point of adding a system to application, this one instead relies on deterministically deriving simple states from more complex ones. As a result, it does not require any special macros, nor does it change any other interactions with the state system once you define and add your derived state. It also maintains a degree of distinction between `State` and just normal application state - your derivations have to end up being discreet pre-determined values, meaning there is less of a risk/temptation to place a significant amount of logic and data within a given state. ### Addition - Sub States closes #9942 After some conversation with Maintainers & SMEs, a significant concern was that people might attempt to use this feature as if it were sub-states, and find themselves unable to use it appropriately. Since `ComputedState` is mainly a state matching feature, while `SubStates` are more of a state mutation related feature - but one that is easy to add with the help of the machinery introduced by `ComputedState`, it was added here as well. The relevant discussion is here: https://discord.com/channels/691052431525675048/1200556329803186316 ## Solution closes #11358 The solution is to create a new type of state - one implementing `ComputedStates` - which is deterministically tied to one or more other states. Implementors write a function to transform the source states into the computed state, and it gets triggered whenever one of the source states changes. In addition, we added the `FreelyMutableState` trait , which is implemented as part of the derive macro for `States`. This allows us to limit use of `NextState<S>` to states that are actually mutable, preventing mis-use of `ComputedStates`. --- ## Changelog - Added `ComputedStates` trait - Added `FreelyMutableState` trait - Converted `NextState` resource to an Enum, with `Unchanged` and `Pending` - Added `App::add_computed_state::<S: ComputedStates>()`, to allow for easily adding derived states to an App. - Moved the `StateTransition` schedule label from `bevy_app` to `bevy_ecs` - but maintained the export in `bevy_app` for continuity. - Modified the process for updating states. Instead of just having an `apply_state_transition` system that can be added anywhere, we now have a multi-stage process that has to run within the `StateTransition` label. First, all the state changes are calculated - manual transitions rely on `apply_state_transition`, while computed transitions run their computation process before both call `internal_apply_state_transition` to apply the transition, send out the transition event, trigger dependent states, and record which exit/transition/enter schedules need to occur. Once all the states have been updated, the transition schedules are called - first the exit schedules, then transition schedules and finally enter schedules. - Added `SubStates` trait - Adjusted `apply_state_transition` to be a no-op if the `State<S>` resource doesn't exist ## Migration Guide If the user accessed the NextState resource's value directly or created them from scratch they will need to adjust to use the new enum variants: - if they created a `NextState(Some(S))` - they should now use `NextState::Pending(S)` - if they created a `NextState(None)` -they should now use `NextState::Unchanged` - if they matched on the `NextState` value, they would need to make the adjustments above If the user manually utilized `apply_state_transition`, they should instead use systems that trigger the `StateTransition` schedule. --- ## Future Work There is still some future potential work in the area, but I wanted to keep these potential features and changes separate to keep the scope here contained, and keep the core of it easy to understand and use. However, I do want to note some of these things, both as inspiration to others and an illustration of what this PR could unlock. - `NextState::Remove` - Now that the `State` related mechanisms all utilize options (#11417), it's fairly easy to add support for explicit state removal. And while `ComputedStates` can add and remove themselves, right now `FreelyMutableState`s can't be removed from within the state system. While it existed originally in this PR, it is a different question with a separate scope and usability concerns - so having it as it's own future PR seems like the best approach. This feature currently lives in a separate branch in my fork, and the differences between it and this PR can be seen here: https://github.com/lee-orr/bevy/pull/5 - `NextState::ReEnter` - this would allow you to trigger exit & entry systems for the current state type. We can potentially also add a `NextState::ReEnterRecirsive` to also re-trigger any states that depend on the current one. - More mechanisms for `State` updates - This PR would finally make states that aren't a set of exclusive Enums useful, and with that comes the question of setting state more effectively. Right now, to update a state you either need to fully create the new state, or include the `Res<Option<State<S>>>` resource in your system, clone the state, mutate it, and then use `NextState.set(my_mutated_state)` to make it the pending next state. There are a few other potential methods that could be implemented in future PRs: - Inverse Compute States - these would essentially be compute states that have an additional (manually defined) function that can be used to nudge the source states so that they result in the computed states having a given value. For example, you could use set the `IsPaused` state, and it would attempt to pause or unpause the game by modifying the `AppState` as needed. - Closure-based state modification - this would involve adding a `NextState.modify(f: impl Fn(Option<S> -> Option<S>)` method, and then you can pass in closures or function pointers to adjust the state as needed. - Message-based state modification - this would involve either creating states that can respond to specific messages, similar to Elm or Redux. These could either use the `NextState` mechanism or the Event mechanism. - ~`SubStates` - which are essentially a hybrid of computed and manual states. In the simplest (and most likely) version, they would work by having a computed element that determines whether the state should exist, and if it should has the capacity to add a new version in, but then any changes to it's content would be freely mutated.~ this feature is now part of this PR. See above. - Lastly, since states are getting more complex there might be value in moving them out of `bevy_ecs` and into their own crate, or at least out of the `schedule` module into a `states` module. #11087 As mentioned, all these future work elements are TBD and are explicitly not part of this PR - I just wanted to provide them as potential explorations for the future. --------- Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com> Co-authored-by: Marcel Champagne <voiceofmarcel@gmail.com> Co-authored-by: MiniaczQ <xnetroidpl@gmail.com> |
||
Jonathan
|
e9be54b0ea
|
Parallel event reader (#12554)
# Objective Allow parallel iteration over events, resolve #10766 ## Solution - Add `EventParIter` which works similarly to `QueryParIter`, implementing a `for_each{_with_id}` operator. I chose to not mirror `EventIteratorWithId` and instead implement both operations on a single struct. - Reuse `BatchingStrategy` from `QueryParIter` ## Changelog - `EventReader` now supports parallel event iteration using `par_read().for_each(|event| ...)`. --------- Co-authored-by: James Liu <contact@jamessliu.com> Co-authored-by: Pablo Reinhardt <126117294+pablo-lua@users.noreply.github.com> |
||
Martín Maita
|
0c78bf3bb0
|
Moves intern and label modules into bevy_ecs (#12772)
# Objective - Attempts to solve two items from https://github.com/bevyengine/bevy/issues/11478. ## Solution - Moved `intern` module from `bevy_utils` into `bevy_ecs` crate and updated all relevant imports. - Moved `label` module from `bevy_utils` into `bevy_ecs` crate and updated all relevant imports. --- ## Migration Guide - Replace `bevy_utils::define_label` imports with `bevy_ecs::define_label` imports. - Replace `bevy_utils:🏷️:DynEq` imports with `bevy_ecs:🏷️:DynEq` imports. - Replace `bevy_utils:🏷️:DynHash` imports with `bevy_ecs:🏷️:DynHash` imports. - Replace `bevy_utils::intern::Interned` imports with `bevy_ecs::intern::Interned` imports. - Replace `bevy_utils::intern::Internable` imports with `bevy_ecs::intern::Internable` imports. - Replace `bevy_utils::intern::Interner` imports with `bevy_ecs::intern::Interner` imports. --------- Co-authored-by: James Liu <contact@jamessliu.com> |
||
James Liu
|
56bcbb0975
|
Forbid unsafe in most crates in the engine (#12684)
# Objective Resolves #3824. `unsafe` code should be the exception, not the norm in Rust. It's obviously needed for various use cases as it's interfacing with platforms and essentially running the borrow checker at runtime in the ECS, but the touted benefits of Bevy is that we are able to heavily leverage Rust's safety, and we should be holding ourselves accountable to that by minimizing our unsafe footprint. ## Solution Deny `unsafe_code` workspace wide. Add explicit exceptions for the following crates, and forbid it in almost all of the others. * bevy_ecs - Obvious given how much unsafe is needed to achieve performant results * bevy_ptr - Works with raw pointers, even more low level than bevy_ecs. * bevy_render - due to needing to integrate with wgpu * bevy_window - due to needing to integrate with raw_window_handle * bevy_utils - Several unsafe utilities used by bevy_ecs. Ideally moved into bevy_ecs instead of made publicly usable. * bevy_reflect - Required for the unsafe type casting it's doing. * bevy_transform - for the parallel transform propagation * bevy_gizmos - For the SystemParam impls it has. * bevy_assets - To support reflection. Might not be required, not 100% sure yet. * bevy_mikktspace - due to being a conversion from a C library. Pending safe rewrite. * bevy_dynamic_plugin - Inherently unsafe due to the dynamic loading nature. Several uses of unsafe were rewritten, as they did not need to be using them: * bevy_text - a case of `Option::unchecked` could be rewritten as a normal for loop and match instead of an iterator. * bevy_color - the Pod/Zeroable implementations were replaceable with bytemuck's derive macros. |
||
|
James Liu
|
f096ad4155
|
Set the logo and favicon for all of Bevy's published crates (#12696)
# Objective Currently the built docs only shows the logo and favicon for the top level `bevy` crate. This makes views like https://docs.rs/bevy_ecs/latest/bevy_ecs/ look potentially unrelated to the project at first glance. ## Solution Reproduce the docs attributes for every crate that Bevy publishes. Ideally this would be done with some workspace level Cargo.toml control, but AFAICT, such support does not exist. |
||
Brezak
|
69e78bd03e
|
Fix Ci failing over dead code in tests (#12623)
# Objective Fix Pr CI failing over dead code in tests and main branch CI failing over a missing semicolon. Fixes #12620. ## Solution Add dead_code annotations and a semicolon. |
||
Al M
|
52e3f2007b
|
Add "all-features = true" to docs.rs metadata for most crates (#12366)
# Objective Fix missing `TextBundle` (and many others) which are present in the main crate as default features but optional in the sub-crate. See: - https://docs.rs/bevy/0.13.0/bevy/ui/node_bundles/index.html - https://docs.rs/bevy_ui/0.13.0/bevy_ui/node_bundles/index.html ~~There are probably other instances in other crates that I could track down, but maybe "all-features = true" should be used by default in all sub-crates? Not sure.~~ (There were many.) I only noticed this because rust-analyzer's "open docs" features takes me to the sub-crate, not the main one. ## Solution Add "all-features = true" to docs.rs metadata for crates that use features. ## Changelog ### Changed - Unified features documented on docs.rs between main crate and sub-crates |
||
|
James Liu
|
512b7463a3
|
Disentangle bevy_utils/bevy_core's reexported dependencies (#12313)
# Objective Make bevy_utils less of a compilation bottleneck. Tackle #11478. ## Solution * Move all of the directly reexported dependencies and move them to where they're actually used. * Remove the UUID utilities that have gone unused since `TypePath` took over for `TypeUuid`. * There was also a extraneous bytemuck dependency on `bevy_core` that has not been used for a long time (since `encase` became the primary way to prepare GPU buffers). * Remove the `all_tuples` macro reexport from bevy_ecs since it's accessible from `bevy_utils`. --- ## Changelog Removed: Many of the reexports from bevy_utils (petgraph, uuid, nonmax, smallvec, and thiserror). Removed: bevy_core's reexports of bytemuck. ## Migration Guide bevy_utils' reexports of petgraph, uuid, nonmax, smallvec, and thiserror have been removed. bevy_core' reexports of bytemuck's types has been removed. Add them as dependencies in your own crate instead. |
||
|
James O'Brien
|
94ff123d7f
|
Component Lifecycle Hooks and a Deferred World (#10756)
# Objective - Provide a reliable and performant mechanism to allows users to keep components synchronized with external sources: closing/opening sockets, updating indexes, debugging etc. - Implement a generic mechanism to provide mutable access to the world without allowing structural changes; this will not only be used here but is a foundational piece for observers, which are key for a performant implementation of relations. ## Solution - Implement a new type `DeferredWorld` (naming is not important, `StaticWorld` is also suitable) that wraps a world pointer and prevents user code from making any structural changes to the ECS; spawning entities, creating components, initializing resources etc. - Add component lifecycle hooks `on_add`, `on_insert` and `on_remove` that can be assigned callbacks in user code. --- ## Changelog - Add new `DeferredWorld` type. - Add new world methods: `register_component::<T>` and `register_component_with_descriptor`. These differ from `init_component` in that they provide mutable access to the created `ComponentInfo` but will panic if the component is already in any archetypes. These restrictions serve two purposes: 1. Prevent users from defining hooks for components that may already have associated hooks provided in another plugin. (a use case better served by observers) 2. Ensure that when an `Archetype` is created it gets the appropriate flags to early-out when triggering hooks. - Add methods to `ComponentInfo`: `on_add`, `on_insert` and `on_remove` to be used to register hooks of the form `fn(DeferredWorld, Entity, ComponentId)` - Modify `BundleInserter`, `BundleSpawner` and `EntityWorldMut` to trigger component hooks when appropriate. - Add bit flags to `Archetype` indicating whether or not any contained components have each type of hook, this can be expanded for other flags as needed. - Add `component_hooks` example to illustrate usage. Try it out! It's fun to mash keys. ## Safety The changes to component insertion, removal and deletion involve a large amount of unsafe code and it's fair for that to raise some concern. I have attempted to document it as clearly as possible and have confirmed that all the hooks examples are accepted by `cargo miri` as not causing any undefined behavior. The largest issue is in ensuring there are no outstanding references when passing a `DeferredWorld` to the hooks which requires some use of raw pointers (as was already happening to some degree in those places) and I have taken some time to ensure that is the case but feel free to let me know if I've missed anything. ## Performance These changes come with a small but measurable performance cost of between 1-5% on `add_remove` benchmarks and between 1-3% on `insert` benchmarks. One consideration to be made is the existence of the current `RemovedComponents` which is on average more costly than the addition of `on_remove` hooks due to the early-out, however hooks doesn't completely remove the need for `RemovedComponents` as there is a chance you want to respond to the removal of a component that already has an `on_remove` hook defined in another plugin, so I have not removed it here. I do intend to deprecate it with the introduction of observers in a follow up PR. ## Discussion Questions - Currently `DeferredWorld` implements `Deref` to `&World` which makes sense conceptually, however it does cause some issues with rust-analyzer providing autocomplete for `&mut World` references which is annoying. There are alternative implementations that may address this but involve more code churn so I have attempted them here. The other alternative is to not implement `Deref` at all but that leads to a large amount of API duplication. - `DeferredWorld`, `StaticWorld`, something else? - In adding support for hooks to `EntityWorldMut` I encountered some unfortunate difficulties with my desired API. If commands are flushed after each call i.e. `world.spawn() // flush commands .insert(A) // flush commands` the entity may be despawned while `EntityWorldMut` still exists which is invalid. An alternative was then to add `self.world.flush_commands()` to the drop implementation for `EntityWorldMut` but that runs into other problems for implementing functions like `into_unsafe_entity_cell`. For now I have implemented a `.flush()` which will flush the commands and consume `EntityWorldMut` or users can manually run `world.flush_commands()` after using `EntityWorldMut`. - In order to allowing querying on a deferred world we need implementations of `WorldQuery` to not break our guarantees of no structural changes through their `UnsafeWorldCell`. All our implementations do this, but there isn't currently any safety documentation specifying what is or isn't allowed for an implementation, just for the caller, (they also shouldn't be aliasing components they didn't specify access for etc.) is that something we should start doing? (see 10752) Please check out the example `component_hooks` or the tests in `bundle.rs` for usage examples. I will continue to expand this description as I go. See #10839 for a more ergonomic API built on top of this one that isn't subject to the same restrictions and supports `SystemParam` dependency injection. |
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SpecificProtagonist
|
21aa5fe2b6
|
Use TypeIdMap whenever possible (#11684)
Use `TypeIdMap<T>` instead of `HashMap<TypeId, T>` - ~~`TypeIdMap` was in `bevy_ecs`. I've kept it there because of #11478~~ - ~~I haven't swapped `bevy_reflect` over because it doesn't depend on `bevy_ecs`, but I'd also be happy with moving `TypeIdMap` to `bevy_utils` and then adding a dependency to that~~ - ~~this is a slight change in the public API of `DrawFunctionsInternal`, does this need to go in the changelog?~~ ## Changelog - moved `TypeIdMap` to `bevy_utils` - changed `DrawFunctionsInternal::indices` to `TypeIdMap` ## Migration Guide - `TypeIdMap` now lives in `bevy_utils` - `DrawFunctionsInternal::indices` now uses a `TypeIdMap`. --------- Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com> |
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Tristan Guichaoua
|
694c06f3d0
|
Inverse missing_docs logic (#11676)
# Objective Currently the `missing_docs` lint is allowed-by-default and enabled at crate level when their documentations is complete (see #3492). This PR proposes to inverse this logic by making `missing_docs` warn-by-default and mark crates with imcomplete docs allowed. ## Solution Makes `missing_docs` warn at workspace level and allowed at crate level when the docs is imcomplete. |
||
|
Tristan Guichaoua
|
b0f5d4df58
|
Enable the unsafe_op_in_unsafe_fn lint (#11591)
# Objective - Partial fix of #11590 ## Solution - Enable `unsafe_op_in_unsafe_fn` at workspace level - Fix the lint for most of the crates |
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|
Charles Bournhonesque
|
9223201d54
|
Make the MapEntities trait generic over Mappers, and add a simpler EntityMapper (#11428)
# Objective My motivation are to resolve some of the issues I describe in this [PR](https://github.com/bevyengine/bevy/issues/11415): - not being able to easily mapping entities because the current EntityMapper requires `&mut World` access - not being able to create my own `EntityMapper` because some components (`Parent` or `Children`) do not provide any public way of modifying the inner entities This PR makes the `MapEntities` trait accept a generic type that implements `Mapper` to perform the mapping. This means we don't need to use `EntityMapper` to perform our mapping, we can use any type that implements `Mapper`. Basically this change is very similar to what `serde` does. Instead of specifying directly how to map entities for a given type, we have 2 distinct steps: - the user implements `MapEntities` to define how the type will be traversed and which `Entity`s will be mapped - the `Mapper` defines how the mapping is actually done This is similar to the distinction between `Serialize` (`MapEntities`) and `Serializer` (`Mapper`). This allows networking library to map entities without having to use the existing `EntityMapper` (which requires `&mut World` access and the use of `world_scope()`) ## Migration Guide - The existing `EntityMapper` (notably used to replicate `Scenes` across different `World`s) has been renamed to `SceneEntityMapper` - The `MapEntities` trait now works with a generic `EntityMapper` instead of the specific struct `EntityMapper`. Calls to `fn map_entities(&mut self, entity_mapper: &mut EntityMapper)` need to be updated to `fn map_entities<M: EntityMapper>(&mut self, entity_mapper: &mut M)` - The new trait `EntityMapper` has been added to the prelude --------- Co-authored-by: Charles Bournhonesque <cbournhonesque@snapchat.com> Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com> Co-authored-by: UkoeHB <37489173+UkoeHB@users.noreply.github.com> |
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Giacomo Stevanato
|
eff96e20a0
|
Add ReflectFromWorld and replace the FromWorld requirement on ReflectComponent and ReflectBundle with FromReflect (#9623)
# Objective
- `FromType<T>` for `ReflectComponent` and `ReflectBundle` currently
require `T: FromWorld` for two reasons:
- they include a `from_world` method;
- they create dummy `T`s using `FromWorld` and then `apply` a `&dyn
Reflect` to it to simulate `FromReflect`.
- However `FromWorld`/`Default` may be difficult/weird/impractical to
implement, while `FromReflect` is easier and also more natural for the
job.
- See also
https://discord.com/channels/691052431525675048/1146022009554337792
## Solution
- Split `from_world` from `ReflectComponent` and `ReflectBundle` into
its own `ReflectFromWorld` struct.
- Replace the requirement on `FromWorld` in `ReflectComponent` and
`ReflectBundle` with `FromReflect`
---
## Changelog
- `ReflectComponent` and `ReflectBundle` no longer offer a `from_world`
method.
- `ReflectComponent` and `ReflectBundle`'s `FromType<T>` implementation
no longer requires `T: FromWorld`, but now requires `FromReflect`.
- `ReflectComponent::insert`, `ReflectComponent::apply_or_insert` and
`ReflectComponent::copy` now take an extra `&TypeRegistry` parameter.
- There is now a new `ReflectFromWorld` struct.
## Migration Guide
- Existing uses of `ReflectComponent::from_world` and
`ReflectBundle::from_world` will have to be changed to
`ReflectFromWorld::from_world`.
- Users of `#[reflect(Component)]` and `#[reflect(Bundle)]` will need to
also implement/derive `FromReflect`.
- Users of `#[reflect(Component)]` and `#[reflect(Bundle)]` may now want
to also add `FromWorld` to the list of reflected traits in case their
`FromReflect` implementation may fail.
- Users of `ReflectComponent` will now need to pass a `&TypeRegistry` to
its `insert`, `apply_or_insert` and `copy` methods.
|
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James O'Brien
|
ea42d14344
|
Dynamic queries and builder API (#9774)
# Objective Expand the existing `Query` API to support more dynamic use cases i.e. scripting. ## Prior Art - #6390 - #8308 - #10037 ## Solution - Create a `QueryBuilder` with runtime methods to define the set of component accesses for a built query. - Create new `WorldQueryData` implementations `FilteredEntityMut` and `FilteredEntityRef` as variants of `EntityMut` and `EntityRef` that provide run time checked access to the components included in a given query. - Add new methods to `Query` to create "query lens" with a subset of the access of the initial query. ### Query Builder The `QueryBuilder` API allows you to define a query at runtime. At it's most basic use it will simply create a query with the corresponding type signature: ```rust let query = QueryBuilder::<Entity, With<A>>::new(&mut world).build(); // is equivalent to let query = QueryState::<Entity, With<A>>::new(&mut world); ``` Before calling `.build()` you also have the opportunity to add additional accesses and filters. Here is a simple example where we add additional filter terms: ```rust let entity_a = world.spawn((A(0), B(0))).id(); let entity_b = world.spawn((A(0), C(0))).id(); let mut query_a = QueryBuilder::<Entity>::new(&mut world) .with::<A>() .without::<C>() .build(); assert_eq!(entity_a, query_a.single(&world)); ``` This alone is useful in that allows you to decide which archetypes your query will match at runtime. However it is also very limited, consider a case like the following: ```rust let query_a = QueryBuilder::<&A>::new(&mut world) // Add an additional access .data::<&B>() .build(); ``` This will grant the query an additional read access to component B however we have no way of accessing the data while iterating as the type signature still only includes &A. For an even more concrete example of this consider dynamic components: ```rust let query_a = QueryBuilder::<Entity>::new(&mut world) // Adding a filter is easy since it doesn't need be read later .with_id(component_id_a) // How do I access the data of this component? .ref_id(component_id_b) .build(); ``` With this in mind the `QueryBuilder` API seems somewhat incomplete by itself, we need some way method of accessing the components dynamically. So here's one: ### Query Transmutation If the problem is not having the component in the type signature why not just add it? This PR also adds transmute methods to `QueryBuilder` and `QueryState`. Here's a simple example: ```rust world.spawn(A(0)); world.spawn((A(1), B(0))); let mut query = QueryBuilder::<()>::new(&mut world) .with::<B>() .transmute::<&A>() .build(); query.iter(&world).for_each(|a| assert_eq!(a.0, 1)); ``` The `QueryState` and `QueryBuilder` transmute methods look quite similar but are different in one respect. Transmuting a builder will always succeed as it will just add the additional accesses needed for the new terms if they weren't already included. Transmuting a `QueryState` will panic in the case that the new type signature would give it access it didn't already have, for example: ```rust let query = QueryState::<&A, Option<&B>>::new(&mut world); /// This is fine, the access for Option<&A> is less restrictive than &A query.transmute::<Option<&A>>(&world); /// Oh no, this would allow access to &B on entities that might not have it, so it panics query.transmute::<&B>(&world); /// This is right out query.transmute::<&C>(&world); ``` This is quite an appealing API to also have available on `Query` however it does pose one additional wrinkle: In order to to change the iterator we need to create a new `QueryState` to back it. `Query` doesn't own it's own state though, it just borrows it, so we need a place to borrow it from. This is why `QueryLens` exists, it is a place to store the new state so it can be borrowed when you call `.query()` leaving you with an API like this: ```rust fn function_that_takes_a_query(query: &Query<&A>) { // ... } fn system(query: Query<(&A, &B)>) { let lens = query.transmute_lens::<&A>(); let q = lens.query(); function_that_takes_a_query(&q); } ``` Now you may be thinking: Hey, wait a second, you introduced the problem with dynamic components and then described a solution that only works for static components! Ok, you got me, I guess we need a bit more: ### Filtered Entity References Currently the only way you can access dynamic components on entities through a query is with either `EntityMut` or `EntityRef`, however these can access all components and so conflict with all other accesses. This PR introduces `FilteredEntityMut` and `FilteredEntityRef` as alternatives that have additional runtime checking to prevent accessing components that you shouldn't. This way you can build a query with a `QueryBuilder` and actually access the components you asked for: ```rust let mut query = QueryBuilder::<FilteredEntityRef>::new(&mut world) .ref_id(component_id_a) .with(component_id_b) .build(); let entity_ref = query.single(&world); // Returns Some(Ptr) as we have that component and are allowed to read it let a = entity_ref.get_by_id(component_id_a); // Will return None even though the entity does have the component, as we are not allowed to read it let b = entity_ref.get_by_id(component_id_b); ``` For the most part these new structs have the exact same methods as their non-filtered equivalents. Putting all of this together we can do some truly dynamic ECS queries, check out the `dynamic` example to see it in action: ``` Commands: comp, c Create new components spawn, s Spawn entities query, q Query for entities Enter a command with no parameters for usage. > c A, B, C, Data 4 Component A created with id: 0 Component B created with id: 1 Component C created with id: 2 Component Data created with id: 3 > s A, B, Data 1 Entity spawned with id: 0v0 > s A, C, Data 0 Entity spawned with id: 1v0 > q &Data 0v0: Data: [1, 0, 0, 0] 1v0: Data: [0, 0, 0, 0] > q B, &mut Data 0v0: Data: [2, 1, 1, 1] > q B || C, &Data 0v0: Data: [2, 1, 1, 1] 1v0: Data: [0, 0, 0, 0] ``` ## Changelog - Add new `transmute_lens` methods to `Query`. - Add new types `QueryBuilder`, `FilteredEntityMut`, `FilteredEntityRef` and `QueryLens` - `update_archetype_component_access` has been removed, archetype component accesses are now determined by the accesses set in `update_component_access` - Added method `set_access` to `WorldQuery`, this is called before `update_component_access` for queries that have a restricted set of accesses, such as those built by `QueryBuilder` or `QueryLens`. This is primarily used by the `FilteredEntity*` variants and has an empty trait implementation. - Added method `get_state` to `WorldQuery` as a fallible version of `init_state` when you don't have `&mut World` access. ## Future Work Improve performance of `FilteredEntityMut` and `FilteredEntityRef`, currently they have to determine the accesses a query has in a given archetype during iteration which is far from ideal, especially since we already did the work when matching the archetype in the first place. To avoid making more internal API changes I have left it out of this PR. --------- Co-authored-by: Mike Hsu <mike.hsu@gmail.com> |
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SpecificProtagonist
|
cd12e7c836
|
Make TypeId::hash more robust in case of upstream rustc changes (#11334)
Based on discussion after #11268 was merged: Instead of panicking should the impl of `TypeId::hash` change significantly, have a fallback and detect this in a test. |
||
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SpecificProtagonist
|
69760c78cf
|
Skip rehashing TypeIds (#11268)
# Objective `TypeId` contains a high-quality hash. Whenever a lookup based on a `TypeId` is performed (e.g. to insert/remove components), the hash is run through a second hash function. This is unnecessary. ## Solution Skip re-hashing `TypeId`s. In my [testing](https://gist.github.com/SpecificProtagonist/4b49ad74c6b82b0aedd3b4ea35121be8), this improves lookup performance consistently by 10%-15% (of course, the lookup is only a small part of e.g. a bundle insertion). |
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Gonçalo Rica Pais da Silva
|
e6a324a11a
|
Unified identifer for entities & relations (#9797)
# Objective The purpose of this PR is to begin putting together a unified identifier structure that can be used by entities and later components (as entities) as well as relationship pairs for relations, to enable all of these to be able to use the same storages. For the moment, to keep things small and focused, only `Entity` is being changed to make use of the new `Identifier` type, keeping `Entity`'s API and serialization/deserialization the same. Further changes are for follow-up PRs. ## Solution `Identifier` is a wrapper around `u64` split into two `u32` segments with the idea of being generalised to not impose restrictions on variants. That is for `Entity` to do. Instead, it is a general API for taking bits to then merge and map into a `u64` integer. It exposes low/high methods to return the two value portions as `u32` integers, with then the MSB masked for usage as a type flag, enabling entity kind discrimination and future activation/deactivation semantics. The layout in this PR for `Identifier` is described as below, going from MSB -> LSB. ``` |F| High value | Low value | |_|_______________________________|________________________________| |1| 31 | 32 | F = Bit Flags ``` The high component in this implementation has only 31 bits, but that still leaves 2^31 or 2,147,483,648 values that can be stored still, more than enough for any generation/relation kinds/etc usage. The low part is a full 32-bit index. The flags allow for 1 bit to be used for entity/pair discrimination, as these have different usages for the low/high portions of the `Identifier`. More bits can be reserved for more variants or activation/deactivation purposes, but this currently has no use in bevy. More bits could be reserved for future features at the cost of bits for the high component, so how much to reserve is up for discussion. Also, naming of the struct and methods are also subject to further bikeshedding and feedback. Also, because IDs can have different variants, I wonder if `Entity::from_bits` needs to return a `Result` instead of potentially panicking on receiving an invalid ID. PR is provided as an early WIP to obtain feedback and notes on whether this approach is viable. --- ## Changelog ### Added New `Identifier` struct for unifying IDs. ### Changed `Entity` changed to use new `Identifier`/`IdentifierMask` as the underlying ID logic. --------- Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com> Co-authored-by: vero <email@atlasdostal.com> |
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Natalie Bonnibel Baker
|
b257fffef8
|
Change Entity::generation from u32 to NonZeroU32 for niche optimization (#9907)
# Objective - Implements change described in https://github.com/bevyengine/bevy/issues/3022 - Goal is to allow Entity to benefit from niche optimization, especially in the case of Option<Entity> to reduce memory overhead with structures with empty slots ## Discussion - First PR attempt: https://github.com/bevyengine/bevy/pull/3029 - Discord: https://discord.com/channels/691052431525675048/1154573759752183808/1154573764240093224 ## Solution - Change `Entity::generation` from u32 to NonZeroU32 to allow for niche optimization. - The reason for changing generation rather than index is so that the costs are only encountered on Entity free, instead of on Entity alloc - There was some concern with generations being used, due to there being some desire to introduce flags. This was more to do with the original retirement approach, however, in reality even if generations were reduced to 24-bits, we would still have 16 million generations available before wrapping and current ideas indicate that we would be using closer to 4-bits for flags. - Additionally, another concern was the representation of relationships where NonZeroU32 prevents us using the full address space, talking with Joy it seems unlikely to be an issue. The majority of the time these entity references will be low-index entries (ie. `ChildOf`, `Owes`), these will be able to be fast lookups, and the remainder of the range can use slower lookups to map to the address space. - It has the additional benefit of being less visible to most users, since generation is only ever really set through `from_bits` type methods. - `EntityMeta` was changed to match - On free, generation now explicitly wraps: - Originally, generation would panic in debug mode and wrap in release mode due to using regular ops. - The first attempt at this PR changed the behavior to "retire" slots and remove them from use when generations overflowed. This change was controversial, and likely needs a proper RFC/discussion. - Wrapping matches current release behaviour, and should therefore be less controversial. - Wrapping also more easily migrates to the retirement approach, as users likely to exhaust the exorbitant supply of generations will code defensively against aliasing and that defensive code is less likely to break than code assuming that generations don't wrap. - We use some unsafe code here when wrapping generations, to avoid branch on NonZeroU32 construction. It's guaranteed safe due to how we perform wrapping and it results in significantly smaller ASM code. - https://godbolt.org/z/6b6hj8PrM ## Migration - Previous `bevy_scene` serializations have a high likelihood of being broken, as they contain 0th generation entities. ## Current Issues - `Entities::reserve_generations` and `EntityMapper` wrap now, even in debug - although they technically did in release mode already so this probably isn't a huge issue. It just depends if we need to change anything here? --------- Co-authored-by: Natalie Baker <natalie.baker@advancednavigation.com> |
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Connor King
|
1260b7bcf1
|
StateTransitionEvent (#11089)
# Objective
- Make it possible to react to arbitrary state changes
- this will be useful regardless of the other changes to states
currently being discussed
## Solution
- added `StateTransitionEvent<S>` struct
- previously, this would have been impossible:
```rs
#[derive(States, Eq, PartialEq, Hash, Copy, Clone, Default)]
enum MyState {
#[default]
Foo,
Bar(MySubState),
}
enum MySubState {
Spam,
Eggs,
}
app.add_system(Update, on_enter_bar);
fn on_enter_bar(trans: EventReader<StateTransition<MyState>>){
for (befoare, after) in trans.read() {
match before, after {
MyState::Foo, MyState::Bar(_) => info!("detected transition foo => bar");
_, _ => ();
}
}
}
```
---
## Changelog
- Added
- `StateTransitionEvent<S>` - Fired on state changes of `S`
## Migration Guide
N/A no breaking changes
---------
Co-authored-by: Federico Rinaldi <gisquerin@gmail.com>
|
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Mantas
|
5af2f022d8
|
Rename WorldQueryData & WorldQueryFilter to QueryData & QueryFilter (#10779)
# Rename `WorldQueryData` & `WorldQueryFilter` to `QueryData` & `QueryFilter` Fixes #10776 ## Solution Traits `WorldQueryData` & `WorldQueryFilter` were renamed to `QueryData` and `QueryFilter`, respectively. Related Trait types were also renamed. --- ## Changelog - Trait `WorldQueryData` has been renamed to `QueryData`. Derive macro's `QueryData` attribute `world_query_data` has been renamed to `query_data`. - Trait `WorldQueryFilter` has been renamed to `QueryFilter`. Derive macro's `QueryFilter` attribute `world_query_filter` has been renamed to `query_filter`. - Trait's `ExtractComponent` type `Query` has been renamed to `Data`. - Trait's `GetBatchData` types `Query` & `QueryFilter` has been renamed to `Data` & `Filter`, respectively. - Trait's `ExtractInstance` type `Query` has been renamed to `Data`. - Trait's `ViewNode` type `ViewQuery` has been renamed to `ViewData`. - Trait's `RenderCommand` types `ViewWorldQuery` & `ItemWorldQuery` has been renamed to `ViewData` & `ItemData`, respectively. ## Migration Guide Note: if merged before 0.13 is released, this should instead modify the migration guide of #10776 with the updated names. - Rename `WorldQueryData` & `WorldQueryFilter` trait usages to `QueryData` & `QueryFilter` and their respective derive macro attributes `world_query_data` & `world_query_filter` to `query_data` & `query_filter`. - Rename the following trait type usages: - Trait's `ExtractComponent` type `Query` to `Data`. - Trait's `GetBatchData` type `Query` to `Data`. - Trait's `ExtractInstance` type `Query` to `Data`. - Trait's `ViewNode` type `ViewQuery` to `ViewData`' - Trait's `RenderCommand` types `ViewWolrdQuery` & `ItemWorldQuery` to `ViewData` & `ItemData`, respectively. ```rust // Before #[derive(WorldQueryData)] #[world_query_data(derive(Debug))] struct EmptyQuery { empty: (), } // After #[derive(QueryData)] #[query_data(derive(Debug))] struct EmptyQuery { empty: (), } // Before #[derive(WorldQueryFilter)] struct CustomQueryFilter<T: Component, P: Component> { _c: With<ComponentC>, _d: With<ComponentD>, _or: Or<(Added<ComponentC>, Changed<ComponentD>, Without<ComponentZ>)>, _generic_tuple: (With<T>, With<P>), } // After #[derive(QueryFilter)] struct CustomQueryFilter<T: Component, P: Component> { _c: With<ComponentC>, _d: With<ComponentD>, _or: Or<(Added<ComponentC>, Changed<ComponentD>, Without<ComponentZ>)>, _generic_tuple: (With<T>, With<P>), } // Before impl ExtractComponent for ContrastAdaptiveSharpeningSettings { type Query = &'static Self; type Filter = With<Camera>; type Out = (DenoiseCAS, CASUniform); fn extract_component(item: QueryItem<Self::Query>) -> Option<Self::Out> { //... } } // After impl ExtractComponent for ContrastAdaptiveSharpeningSettings { type Data = &'static Self; type Filter = With<Camera>; type Out = (DenoiseCAS, CASUniform); fn extract_component(item: QueryItem<Self::Data>) -> Option<Self::Out> { //... } } // Before impl GetBatchData for MeshPipeline { type Param = SRes<RenderMeshInstances>; type Query = Entity; type QueryFilter = With<Mesh3d>; type CompareData = (MaterialBindGroupId, AssetId<Mesh>); type BufferData = MeshUniform; fn get_batch_data( mesh_instances: &SystemParamItem<Self::Param>, entity: &QueryItem<Self::Query>, ) -> (Self::BufferData, Option<Self::CompareData>) { // .... } } // After impl GetBatchData for MeshPipeline { type Param = SRes<RenderMeshInstances>; type Data = Entity; type Filter = With<Mesh3d>; type CompareData = (MaterialBindGroupId, AssetId<Mesh>); type BufferData = MeshUniform; fn get_batch_data( mesh_instances: &SystemParamItem<Self::Param>, entity: &QueryItem<Self::Data>, ) -> (Self::BufferData, Option<Self::CompareData>) { // .... } } // Before impl<A> ExtractInstance for AssetId<A> where A: Asset, { type Query = Read<Handle<A>>; type Filter = (); fn extract(item: QueryItem<'_, Self::Query>) -> Option<Self> { Some(item.id()) } } // After impl<A> ExtractInstance for AssetId<A> where A: Asset, { type Data = Read<Handle<A>>; type Filter = (); fn extract(item: QueryItem<'_, Self::Data>) -> Option<Self> { Some(item.id()) } } // Before impl ViewNode for PostProcessNode { type ViewQuery = ( &'static ViewTarget, &'static PostProcessSettings, ); fn run( &self, _graph: &mut RenderGraphContext, render_context: &mut RenderContext, (view_target, _post_process_settings): QueryItem<Self::ViewQuery>, world: &World, ) -> Result<(), NodeRunError> { // ... } } // After impl ViewNode for PostProcessNode { type ViewData = ( &'static ViewTarget, &'static PostProcessSettings, ); fn run( &self, _graph: &mut RenderGraphContext, render_context: &mut RenderContext, (view_target, _post_process_settings): QueryItem<Self::ViewData>, world: &World, ) -> Result<(), NodeRunError> { // ... } } // Before impl<P: CachedRenderPipelinePhaseItem> RenderCommand<P> for SetItemPipeline { type Param = SRes<PipelineCache>; type ViewWorldQuery = (); type ItemWorldQuery = (); #[inline] fn render<'w>( item: &P, _view: (), _entity: (), pipeline_cache: SystemParamItem<'w, '_, Self::Param>, pass: &mut TrackedRenderPass<'w>, ) -> RenderCommandResult { // ... } } // After impl<P: CachedRenderPipelinePhaseItem> RenderCommand<P> for SetItemPipeline { type Param = SRes<PipelineCache>; type ViewData = (); type ItemData = (); #[inline] fn render<'w>( item: &P, _view: (), _entity: (), pipeline_cache: SystemParamItem<'w, '_, Self::Param>, pass: &mut TrackedRenderPass<'w>, ) -> RenderCommandResult { // ... } } ``` |
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James Liu
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2148518758
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Override QueryIter::fold to port Query::for_each perf gains to select Iterator combinators (#6773)
# Objective After #6547, `Query::for_each` has been capable of automatic vectorization on certain queries, which is seeing a notable (>50% CPU time improvements) for iteration. However, `Query::for_each` isn't idiomatic Rust, and lacks the flexibility of iterator combinators. Ideally, `Query::iter` and friends should be able to achieve the same results. However, this does seem to blocked upstream (rust-lang/rust#104914) by Rust's loop optimizations. ## Solution This is an intermediate solution and refactor. This moves the `Query::for_each` implementation onto the `Iterator::fold` implementation for `QueryIter` instead. This should result in the same automatic vectorization optimization on all `Iterator` functions that internally use fold, including `Iterator::for_each`, `Iterator::count`, etc. With this, it should close the gap between the two completely. Internally, this PR changes `Query::for_each` to use `query.iter().for_each(..)` instead of the duplicated implementation. Separately, the duplicate implementations of internal iteration (i.e. `Query::par_for_each`) now use portions of the current `Query::for_each` implementation factored out into their own functions. This also massively cleans up our internal fragmentation of internal iteration options, deduplicating the iteration code used in `for_each` and `par_iter().for_each()`. --- ## Changelog Changed: `Query::for_each`, `Query::for_each_mut`, `Query::for_each`, and `Query::for_each_mut` have been moved to `QueryIter`'s `Iterator::for_each` implementation, and still retains their performance improvements over normal iteration. These APIs are deprecated in 0.13 and will be removed in 0.14. --------- Co-authored-by: JoJoJet <21144246+JoJoJet@users.noreply.github.com> Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com> |
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Mark Wainwright
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f0a8994f55
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Split WorldQuery into WorldQueryData and WorldQueryFilter (#9918)
# Objective - Fixes #7680 - This is an updated for https://github.com/bevyengine/bevy/pull/8899 which had the same objective but fell a long way behind the latest changes ## Solution The traits `WorldQueryData : WorldQuery` and `WorldQueryFilter : WorldQuery` have been added and some of the types and functions from `WorldQuery` has been moved into them. `ReadOnlyWorldQuery` has been replaced with `ReadOnlyWorldQueryData`. `WorldQueryFilter` is safe (as long as `WorldQuery` is implemented safely). `WorldQueryData` is unsafe - safely implementing it requires that `Self::ReadOnly` is a readonly version of `Self` (this used to be a safety requirement of `WorldQuery`) The type parameters `Q` and `F` of `Query` must now implement `WorldQueryData` and `WorldQueryFilter` respectively. This makes it impossible to accidentally use a filter in the data position or vice versa which was something that could lead to bugs. ~~Compile failure tests have been added to check this.~~ It was previously sometimes useful to use `Option<With<T>>` in the data position. Use `Has<T>` instead in these cases. The `WorldQuery` derive macro has been split into separate derive macros for `WorldQueryData` and `WorldQueryFilter`. Previously it was possible to derive both `WorldQuery` for a struct that had a mixture of data and filter items. This would not work correctly in some cases but could be a useful pattern in others. *This is no longer possible.* --- ## Notes - The changes outside of `bevy_ecs` are all changing type parameters to the new types, updating the macro use, or replacing `Option<With<T>>` with `Has<T>`. - All `WorldQueryData` types always returned `true` for `IS_ARCHETYPAL` so I moved it to `WorldQueryFilter` and replaced all calls to it with `true`. That should be the only logic change outside of the macro generation code. - `Changed<T>` and `Added<T>` were being generated by a macro that I have expanded. Happy to revert that if desired. - The two derive macros share some functions for implementing `WorldQuery` but the tidiest way I could find to implement them was to give them a ton of arguments and ask clippy to ignore that. ## Changelog ### Changed - Split `WorldQuery` into `WorldQueryData` and `WorldQueryFilter` which now have separate derive macros. It is not possible to derive both for the same type. - `Query` now requires that the first type argument implements `WorldQueryData` and the second implements `WorldQueryFilter` ## Migration Guide - Update derives ```rust // old #[derive(WorldQuery)] #[world_query(mutable, derive(Debug))] struct CustomQuery { entity: Entity, a: &'static mut ComponentA } #[derive(WorldQuery)] struct QueryFilter { _c: With<ComponentC> } // new #[derive(WorldQueryData)] #[world_query_data(mutable, derive(Debug))] struct CustomQuery { entity: Entity, a: &'static mut ComponentA, } #[derive(WorldQueryFilter)] struct QueryFilter { _c: With<ComponentC> } ``` - Replace `Option<With<T>>` with `Has<T>` ```rust /// old fn my_system(query: Query<(Entity, Option<With<ComponentA>>)>) { for (entity, has_a_option) in query.iter(){ let has_a:bool = has_a_option.is_some(); //todo!() } } /// new fn my_system(query: Query<(Entity, Has<ComponentA>)>) { for (entity, has_a) in query.iter(){ //todo!() } } ``` - Fix queries which had filters in the data position or vice versa. ```rust // old fn my_system(query: Query<(Entity, With<ComponentA>)>) { for (entity, _) in query.iter(){ //todo!() } } // new fn my_system(query: Query<Entity, With<ComponentA>>) { for entity in query.iter(){ //todo!() } } // old fn my_system(query: Query<AnyOf<(&ComponentA, With<ComponentB>)>>) { for (entity, _) in query.iter(){ //todo!() } } // new fn my_system(query: Query<Option<&ComponentA>, Or<(With<ComponentA>, With<ComponentB>)>>) { for entity in query.iter(){ //todo!() } } ``` --------- Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com> |
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Mike
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11b1b3a24f
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delete methods deprecated in 0.12 (#10693)
## Changelog - delete methods deprecated in 0.12 |
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TheBigCheese
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e67cfdf82b
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Enable clippy::undocumented_unsafe_blocks warning across the workspace (#10646)
# Objective Enables warning on `clippy::undocumented_unsafe_blocks` across the workspace rather than only in `bevy_ecs`, `bevy_transform` and `bevy_utils`. This adds a little awkwardness in a few areas of code that have trivial safety or explain safety for multiple unsafe blocks with one comment however automatically prevents these comments from being missed. ## Solution This adds `undocumented_unsafe_blocks = "warn"` to the workspace `Cargo.toml` and fixes / adds a few missed safety comments. I also added `#[allow(clippy::undocumented_unsafe_blocks)]` where the safety is explained somewhere above. There are a couple of safety comments I added I'm not 100% sure about in `bevy_animation` and `bevy_render/src/view` and I'm not sure about the use of `#[allow(clippy::undocumented_unsafe_blocks)]` compared to adding comments like `// SAFETY: See above`. |
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Konstantin Kostiuk
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eeb0c2f2e4
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Allow #[derive(Bundle)] on tuple structs (take 3) (#10561)
- rework of old @Veykril's work in [2499](https://github.com/bevyengine/bevy/pull/2499) - Fixes [3537](https://github.com/bevyengine/bevy/issues/3537) |
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Ame
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951c9bb1a2
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Add [lints] table, fix adding #![allow(clippy::type_complexity)] everywhere (#10011)
# Objective - Fix adding `#![allow(clippy::type_complexity)]` everywhere. like #9796 ## Solution - Use the new [lints] table that will land in 1.74 (https://doc.rust-lang.org/nightly/cargo/reference/unstable.html#lints) - inherit lint to the workspace, crates and examples. ``` [lints] workspace = true ``` ## Changelog - Bump rust version to 1.74 - Enable lints table for the workspace ```toml [workspace.lints.clippy] type_complexity = "allow" ``` - Allow type complexity for all crates and examples ```toml [lints] workspace = true ``` --------- Co-authored-by: Martín Maita <47983254+mnmaita@users.noreply.github.com> |
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Pixelstorm
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faa1b57de5
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Global TaskPool API improvements (#10008)
# Objective Reduce code duplication and improve APIs of Bevy's [global taskpools](https://github.com/bevyengine/bevy/blob/main/crates/bevy_tasks/src/usages.rs). ## Solution - As all three of the global taskpools have identical implementations and only differ in their identifiers, this PR moves the implementation into a macro to reduce code duplication. - The `init` method is renamed to `get_or_init` to more accurately reflect what it really does. - Add a new `try_get` method that just returns `None` when the pool is uninitialized, to complement the other getter methods. - Minor documentation improvements to accompany the above changes. --- ## Changelog - Added a new `try_get` method to the global TaskPools - The global TaskPools' `init` method has been renamed to `get_or_init` for clarity - Documentation improvements ## Migration Guide - Uses of `ComputeTaskPool::init`, `AsyncComputeTaskPool::init` and `IoTaskPool::init` should be changed to `::get_or_init`. |
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Joseph
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8eb6ccdd87
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Remove useless single tuples and trailing commas (#9720)
# Objective Title |