//! [Lp spaces](https://en.wikipedia.org/wiki/Lp_space).
use crate::coords::Coordinates;
use num_traits::real::Real;
use num_traits::zero;
/// A point in L1 space.
pub use crate::taxi::Taxicab as L1;
/// Compute the L1 distance between two points.
pub use crate::taxi::taxicab_distance as l1_distance;
/// A point in L2 space.
pub use crate::euclid::Euclidean as L2;
/// An L2 distance.
pub use crate::euclid::EuclideanDistance as L2Distance;
/// Compute the L2 distance between two points.
pub use crate::euclid::euclidean_distance as l2_distance;
/// A point in L∞ space.
pub use crate::chebyshev::Chebyshev as Linf;
/// Compute the L∞ distance between two points.
pub use crate::chebyshev::chebyshev_distance as linf_distance;
/// Compute the [Lp distance] between two points.
///
/// [Lp distance]: https://en.wikipedia.org/wiki/Lp_space
pub fn lp_distance(p: T::Value, x: T, y: U) -> T::Value
where
T: Coordinates,
U: Coordinates,
T::Value: Real,
{
debug_assert!(x.dims() == y.dims());
let mut sum: T::Value = zero();
for i in 0..x.dims() {
sum += (x.coord(i) - y.coord(i)).abs().powf(p);
}
sum.powf(p.recip())
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_lp_distance() {
assert_eq!(l1_distance(&[0.0, 0.0], &[3.0, 4.0]), 7.0);
assert_eq!(l2_distance(&[0.0, 0.0], &[3.0, 4.0]), 5.0);
assert!(lp_distance(3.0, &[0.0, 0.0], &[3.0, 4.0]) < 5.0);
assert_eq!(linf_distance(&[0.0, 0.0], &[3.0, 4.0]), 4.0);
}
}