Trait bevy::prelude::DetectChangesMut
pub trait DetectChangesMut: DetectChanges {
type Inner: ?Sized;
// Required methods
fn set_changed(&mut self);
fn set_last_changed(&mut self, last_changed: Tick);
fn bypass_change_detection(&mut self) -> &mut Self::Inner;
// Provided methods
fn set_if_neq(&mut self, value: Self::Inner) -> bool
where Self::Inner: Sized + PartialEq { ... }
fn replace_if_neq(&mut self, value: Self::Inner) -> Option<Self::Inner>
where Self::Inner: Sized + PartialEq { ... }
}Expand description
Types that implement reliable change detection.
§Example
Using types that implement DetectChangesMut, such as ResMut, provide
a way to query if a value has been mutated in another system.
Normally change detection is triggered by either DerefMut or AsMut, however
it can be manually triggered via set_changed.
To ensure that changes are only triggered when the value actually differs,
check if the value would change before assignment, such as by checking that new != old.
You must be sure that you are not mutably dereferencing in this process.
set_if_neq is a helper
method for this common functionality.
use bevy_ecs::prelude::*;
#[derive(Resource)]
struct MyResource(u32);
fn my_system(mut resource: ResMut<MyResource>) {
if resource.is_changed() {
println!("My resource was mutated!");
}
resource.0 = 42; // triggers change detection via [`DerefMut`]
}Required Associated Types§
Required Methods§
fn set_changed(&mut self)
fn set_changed(&mut self)
Flags this value as having been changed.
Mutably accessing this smart pointer will automatically flag this value as having been changed. However, mutation through interior mutability requires manual reporting.
Note: This operation cannot be undone.
fn set_last_changed(&mut self, last_changed: Tick)
fn set_last_changed(&mut self, last_changed: Tick)
Manually sets the change tick recording the time when this data was last mutated.
§Warning
This is a complex and error-prone operation, primarily intended for use with rollback networking strategies.
If you merely want to flag this data as changed, use set_changed instead.
If you want to avoid triggering change detection, use bypass_change_detection instead.
fn bypass_change_detection(&mut self) -> &mut Self::Inner
fn bypass_change_detection(&mut self) -> &mut Self::Inner
Manually bypasses change detection, allowing you to mutate the underlying value without updating the change tick.
§Warning
This is a risky operation, that can have unexpected consequences on any system relying on this code. However, it can be an essential escape hatch when, for example, you are trying to synchronize representations using change detection and need to avoid infinite recursion.
Provided Methods§
fn set_if_neq(&mut self, value: Self::Inner) -> bool
fn set_if_neq(&mut self, value: Self::Inner) -> bool
Overwrites this smart pointer with the given value, if and only if *self != value.
Returns true if the value was overwritten, and returns false if it was not.
This is useful to ensure change detection is only triggered when the underlying value changes, instead of every time it is mutably accessed.
If you’re dealing with non-trivial structs which have multiple fields of non-trivial size,
then consider applying a map_unchanged beforehand to allow changing only the relevant
field and prevent unnecessary copying and cloning.
See the docs of Mut::map_unchanged, MutUntyped::map_unchanged,
ResMut::map_unchanged or NonSendMut::map_unchanged for an example
If you need the previous value, use replace_if_neq.
§Examples
#[derive(Resource, PartialEq, Eq)]
pub struct Score(u32);
fn reset_score(mut score: ResMut<Score>) {
// Set the score to zero, unless it is already zero.
score.set_if_neq(Score(0));
}Examples found in repository?
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fn change_component(time: Res<Time>, mut query: Query<(Entity, &mut MyComponent)>) {
for (entity, mut component) in &mut query {
if rand::thread_rng().gen_bool(0.1) {
info!("changing component {:?}", entity);
let new_component = MyComponent(time.elapsed_seconds().round());
// Change detection occurs on mutable dereference,
// and does not consider whether or not a value is actually equal.
// To avoid triggering change detection when nothing has actually changed,
// you can use the `set_if_neq` method on any component or resource that implements PartialEq
component.set_if_neq(new_component);
}
}
}fn replace_if_neq(&mut self, value: Self::Inner) -> Option<Self::Inner>
fn replace_if_neq(&mut self, value: Self::Inner) -> Option<Self::Inner>
Overwrites this smart pointer with the given value, if and only if *self != value,
returning the previous value if this occurs.
This is useful to ensure change detection is only triggered when the underlying value changes, instead of every time it is mutably accessed.
If you’re dealing with non-trivial structs which have multiple fields of non-trivial size,
then consider applying a map_unchanged beforehand to allow
changing only the relevant field and prevent unnecessary copying and cloning.
See the docs of Mut::map_unchanged, MutUntyped::map_unchanged,
ResMut::map_unchanged or NonSendMut::map_unchanged for an example
If you don’t need the previous value, use set_if_neq.
§Examples
#[derive(Resource, PartialEq, Eq)]
pub struct Score(u32);
#[derive(Event, PartialEq, Eq)]
pub struct ScoreChanged {
current: u32,
previous: u32,
}
fn reset_score(mut score: ResMut<Score>, mut score_changed: EventWriter<ScoreChanged>) {
// Set the score to zero, unless it is already zero.
let new_score = 0;
if let Some(Score(previous_score)) = score.replace_if_neq(Score(new_score)) {
// If `score` change, emit a `ScoreChanged` event.
score_changed.send(ScoreChanged {
current: new_score,
previous: previous_score,
});
}
}