veloren/common/src/util/spatial_grid.rs

use vek::*;

#[derive(Debug)]
pub struct SpatialGrid {
    // Uses two scales of grids so that we can have a hard limit on how far to search in the
    // smaller grid
    grid: hashbrown::HashMap<Vec2<i32>, Vec<specs::Entity>>,
    large_grid: hashbrown::HashMap<Vec2<i32>, Vec<specs::Entity>>,
    // Log base 2 of the cell size of the spatial grid
    lg2_cell_size: usize,
    // Log base 2 of the cell size of the large spatial grid
    lg2_large_cell_size: usize,
    // Entities with a radius over this value are store in the coarser large_grid
    // This is the amount of buffer space we need to add when finding the intersections with cells
    // in the regular grid
    radius_cutoff: u32,
    // Stores the largest radius of the entities in the large_grid
    // This is the amount of buffer space we need to add when finding the intersections with cells
    // in the larger grid
    // note: could explore some distance field type thing for querying whether there are large
    // entities nearby that necessitate expanding the cells searched for collision (and querying
    // how much it needs to be expanded)
    // TODO: log this to metrics?
    largest_large_radius: u32,
}

impl SpatialGrid {
    pub fn new(lg2_cell_size: usize, lg2_large_cell_size: usize, radius_cutoff: u32) -> Self {
        Self {
            grid: Default::default(),
            large_grid: Default::default(),
            lg2_cell_size,
            lg2_large_cell_size,
            radius_cutoff,
            largest_large_radius: radius_cutoff,
        }
    }

    /// Add an entity at the provided 2d pos into the spatial grid
    pub fn insert(&mut self, pos: Vec2<i32>, radius: u32, entity: specs::Entity) {
        if radius <= self.radius_cutoff {
            let cell = pos.map(|e| e >> self.lg2_cell_size);
            self.grid.entry(cell).or_default().push(entity);
        } else {
            let cell = pos.map(|e| e >> self.lg2_large_cell_size);
            self.large_grid.entry(cell).or_default().push(entity);
            self.largest_large_radius = self.largest_large_radius.max(radius);
        }
    }

    /// Get an iterator over the entities overlapping the
    /// provided axis aligned bounding region
    /// NOTE: for best optimization of the iterator use `for_each` rather than a
    /// for loop
    pub fn in_aabr<'a>(&'a self, aabr: Aabr<i32>) -> impl Iterator<Item = specs::Entity> + 'a {
        let iter = |max_entity_radius, grid: &'a hashbrown::HashMap<_, _>, lg2_cell_size| {
            // Add buffer for other entity radius
            let min = aabr.min - max_entity_radius as i32;
            let max = aabr.max + max_entity_radius as i32;
            // Convert to cells
            let min = min.map(|e| e >> lg2_cell_size);
            let max = max.map(|e| (e + (1 << lg2_cell_size) - 1) >> lg2_cell_size);

            (min.x..=max.x)
                .flat_map(move |x| (min.y..=max.y).map(move |y| Vec2::new(x, y)))
                .flat_map(move |cell| grid.get(&cell).into_iter().flatten())
                .copied()
        };

        iter(self.radius_cutoff, &self.grid, self.lg2_cell_size).chain(iter(
            self.largest_large_radius,
            &self.large_grid,
            self.lg2_large_cell_size,
        ))
    }

    /// Get an iterator over the entities overlapping the
    /// axis aligned bounding region that contains the provided circle
    /// NOTE: for best optimization of the iterator use `for_each` rather than a
    /// for loop
    // TODO: using the circle directly would be tighter (how efficient would it be
    // to query the cells intersecting a circle?) (note: if doing this rename
    // the function)
    pub fn in_circle_aabr(
        &self,
        center: Vec2<f32>,
        radius: f32,
    ) -> impl Iterator<Item = specs::Entity> + '_ {
        let center = center.map(|e| e as i32);
        let radius = radius.ceil() as i32;
        // From conversion of center above
        const CENTER_TRUNCATION_ERROR: i32 = 1;
        let max_dist = radius + CENTER_TRUNCATION_ERROR;

        let aabr = Aabr {
            min: center - max_dist,
            max: center + max_dist,
        };

        self.in_aabr(aabr)
    }

    pub fn clear(&mut self) {
        self.grid.clear();
        self.large_grid.clear();
        self.largest_large_radius = self.radius_cutoff;
    }
}
Setup spatial grid for entity versus entity collisions 2021-03-16 05:13:52 +00:00			`use vek::*;`

Revert "Merge branch 'revert-b10718c5' into 'master'" This reverts merge request !2172 2021-04-21 17:10:13 +00:00			`#[derive(Debug)]`
Setup spatial grid for entity versus entity collisions 2021-03-16 05:13:52 +00:00			`pub struct SpatialGrid {`
			`// Uses two scales of grids so that we can have a hard limit on how far to search in the`
			`// smaller grid`
			`grid: hashbrown::HashMap<Vec2<i32>, Vec<specs::Entity>>,`
			`large_grid: hashbrown::HashMap<Vec2<i32>, Vec<specs::Entity>>,`
			`// Log base 2 of the cell size of the spatial grid`
			`lg2_cell_size: usize,`
			`// Log base 2 of the cell size of the large spatial grid`
			`lg2_large_cell_size: usize,`
			`// Entities with a radius over this value are store in the coarser large_grid`
			`// This is the amount of buffer space we need to add when finding the intersections with cells`
			`// in the regular grid`
			`radius_cutoff: u32,`
			`// Stores the largest radius of the entities in the large_grid`
			`// This is the amount of buffer space we need to add when finding the intersections with cells`
			`// in the larger grid`
			`// note: could explore some distance field type thing for querying whether there are large`
			`// entities nearby that necessitate expanding the cells searched for collision (and querying`
			`// how much it needs to be expanded)`
			`// TODO: log this to metrics?`
			`largest_large_radius: u32,`
			`}`

			`impl SpatialGrid {`
			`pub fn new(lg2_cell_size: usize, lg2_large_cell_size: usize, radius_cutoff: u32) -> Self {`
			`Self {`
			`grid: Default::default(),`
			`large_grid: Default::default(),`
			`lg2_cell_size,`
			`lg2_large_cell_size,`
			`radius_cutoff,`
			`largest_large_radius: radius_cutoff,`
			`}`
			`}`

			`/// Add an entity at the provided 2d pos into the spatial grid`
			`pub fn insert(&mut self, pos: Vec2<i32>, radius: u32, entity: specs::Entity) {`
			`if radius <= self.radius_cutoff {`
			`let cell = pos.map(\|e\| e >> self.lg2_cell_size);`
			`self.grid.entry(cell).or_default().push(entity);`
			`} else {`
			`let cell = pos.map(\|e\| e >> self.lg2_large_cell_size);`
			`self.large_grid.entry(cell).or_default().push(entity);`
			`self.largest_large_radius = self.largest_large_radius.max(radius);`
			`}`
			`}`

			`/// Get an iterator over the entities overlapping the`
			`/// provided axis aligned bounding region`
			/// NOTE: for best optimization of the iterator use `for_each` rather than a
			`/// for loop`
			`pub fn in_aabr<'a>(&'a self, aabr: Aabr<i32>) -> impl Iterator<Item = specs::Entity> + 'a {`
			`let iter = \|max_entity_radius, grid: &'a hashbrown::HashMap<_, _>, lg2_cell_size\| {`
			`// Add buffer for other entity radius`
			`let min = aabr.min - max_entity_radius as i32;`
			`let max = aabr.max + max_entity_radius as i32;`
			`// Convert to cells`
			`let min = min.map(\|e\| e >> lg2_cell_size);`
			`let max = max.map(\|e\| (e + (1 << lg2_cell_size) - 1) >> lg2_cell_size);`

			`(min.x..=max.x)`
			`.flat_map(move \|x\| (min.y..=max.y).map(move \|y\| Vec2::new(x, y)))`
			`.flat_map(move \|cell\| grid.get(&cell).into_iter().flatten())`
			`.copied()`
			`};`

			`iter(self.radius_cutoff, &self.grid, self.lg2_cell_size).chain(iter(`
			`self.largest_large_radius,`
			`&self.large_grid,`
			`self.lg2_large_cell_size,`
			`))`
			`}`
Revert "Merge branch 'revert-b10718c5' into 'master'" This reverts merge request !2172 2021-04-21 17:10:13 +00:00
			`/// Get an iterator over the entities overlapping the`
			`/// axis aligned bounding region that contains the provided circle`
			/// NOTE: for best optimization of the iterator use `for_each` rather than a
			`/// for loop`
			`// TODO: using the circle directly would be tighter (how efficient would it be`
			`// to query the cells intersecting a circle?) (note: if doing this rename`
			`// the function)`
			`pub fn in_circle_aabr(`
			`&self,`
			`center: Vec2<f32>,`
			`radius: f32,`
			`) -> impl Iterator<Item = specs::Entity> + '_ {`
			`let center = center.map(\|e\| e as i32);`
			`let radius = radius.ceil() as i32;`
			`// From conversion of center above`
			`const CENTER_TRUNCATION_ERROR: i32 = 1;`
			`let max_dist = radius + CENTER_TRUNCATION_ERROR;`

			`let aabr = Aabr {`
			`min: center - max_dist,`
			`max: center + max_dist,`
			`};`

			`self.in_aabr(aabr)`
			`}`

			`pub fn clear(&mut self) {`
			`self.grid.clear();`
			`self.large_grid.clear();`
			`self.largest_large_radius = self.radius_cutoff;`
			`}`
Setup spatial grid for entity versus entity collisions 2021-03-16 05:13:52 +00:00			`}`