use crate::{archetype::ArchetypeGeneration, schedule::ParallelSystemContainer, world::World}; use downcast_rs::{impl_downcast, Downcast}; pub trait ParallelSystemExecutor: Downcast + Send + Sync { /// Called by `SystemStage` whenever `systems` have been changed. fn rebuild_cached_data(&mut self, systems: &[ParallelSystemContainer]); fn run_systems(&mut self, systems: &mut [ParallelSystemContainer], world: &mut World); } impl_downcast!(ParallelSystemExecutor); pub struct SingleThreadedExecutor { /// Last archetypes generation observed by parallel systems. archetype_generation: ArchetypeGeneration, } impl Default for SingleThreadedExecutor { fn default() -> Self { Self { // MAX ensures access information will be initialized on first run. archetype_generation: ArchetypeGeneration::new(usize::MAX), } } } impl ParallelSystemExecutor for SingleThreadedExecutor { fn rebuild_cached_data(&mut self, _: &[ParallelSystemContainer]) {} fn run_systems(&mut self, systems: &mut [ParallelSystemContainer], world: &mut World) { self.update_archetypes(systems, world); for system in systems { if system.should_run() { system.system_mut().run((), world); } } } } impl SingleThreadedExecutor { /// Calls system.new_archetype() for each archetype added since the last call to [update_archetypes] and /// updates cached archetype_component_access. fn update_archetypes(&mut self, systems: &mut [ParallelSystemContainer], world: &World) { let archetypes = world.archetypes(); let old_generation = self.archetype_generation; let new_generation = archetypes.generation(); if old_generation == new_generation { return; } let archetype_index_range = if old_generation.value() == usize::MAX { 0..archetypes.len() } else { old_generation.value()..archetypes.len() }; for archetype in archetypes.archetypes[archetype_index_range].iter() { for container in systems.iter_mut() { let system = container.system_mut(); system.new_archetype(archetype); } } self.archetype_generation = new_generation; } }