use num_traits::Float;
use ::{Line, LineString, MultiLineString};
use algorithm::euclidean_distance::EuclideanDistance;
pub trait EuclideanLength<T, RHS = Self> {
fn euclidean_length(&self) -> T;
}
impl<T> EuclideanLength<T> for Line<T>
where
T: Float,
{
fn euclidean_length(&self) -> T {
self.start.euclidean_distance(&self.end)
}
}
impl<T> EuclideanLength<T> for LineString<T>
where
T: Float,
{
fn euclidean_length(&self) -> T {
self.lines()
.map(|line| line.euclidean_length())
.fold(T::zero(), |total_length, length| total_length + length)
}
}
impl<T> EuclideanLength<T> for MultiLineString<T>
where
T: Float,
{
fn euclidean_length(&self) -> T {
self.0
.iter()
.fold(T::zero(), |total, line| {
total + line.euclidean_length()
})
}
}
#[cfg(test)]
mod test {
use ::{Coordinate, Line, LineString, MultiLineString, Point};
use algorithm::euclidean_length::EuclideanLength;
#[test]
fn empty_linestring_test() {
let linestring = LineString::<f64>(Vec::new());
assert_eq!(0.0_f64, linestring.euclidean_length());
}
#[test]
fn linestring_one_point_test() {
let linestring = LineString(vec![Point::new(0., 0.)]);
assert_eq!(0.0_f64, linestring.euclidean_length());
}
#[test]
fn linestring_test() {
let p = |x| Point(Coordinate { x: x, y: 1. });
let linestring = LineString(vec![p(1.), p(7.), p(8.), p(9.), p(10.), p(11.)]);
assert_eq!(10.0_f64, linestring.euclidean_length());
}
#[test]
fn multilinestring_test() {
let p = |x, y| Point(Coordinate { x: x, y: y });
let mline = MultiLineString(vec![
LineString(vec![
p(1., 0.),
p(7., 0.),
p(8., 0.),
p(9., 0.),
p(10., 0.),
p(11., 0.),
]),
LineString(vec![p(0., 0.), p(0., 5.)]),
]);
assert_eq!(15.0_f64, mline.euclidean_length());
}
#[test]
fn line_test() {
let line0 = Line::new(Point::new(0., 0.), Point::new(0., 1.));
let line1 = Line::new(Point::new(0., 0.), Point::new(3., 4.));
assert_eq!(line0.euclidean_length(), 1.);
assert_eq!(line1.euclidean_length(), 5.);
}
}