use std::fmt;
use serde::{Deserialize, Serialize};
use geom::{Angle, Distance, PolyLine, Pt2D, Speed};
use crate::{DirectedRoadID, Direction, LaneID, Map, MovementID, PathConstraints, TurnID};
#[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Serialize, Deserialize)]
pub struct Position {
lane: LaneID,
dist_along: Distance,
}
impl fmt::Display for Position {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "Position({}, {})", self.lane, self.dist_along)
}
}
impl Position {
pub fn new(lane: LaneID, dist_along: Distance) -> Position {
Position { lane, dist_along }
}
pub fn start(lane: LaneID) -> Position {
Position {
lane,
dist_along: Distance::ZERO,
}
}
pub fn end(lane: LaneID, map: &Map) -> Position {
Position {
lane,
dist_along: map.get_l(lane).length(),
}
}
pub fn lane(&self) -> LaneID {
self.lane
}
pub fn dist_along(&self) -> Distance {
self.dist_along
}
pub fn pt(&self, map: &Map) -> Pt2D {
match map
.get_l(self.lane)
.lane_center_pts
.dist_along(self.dist_along)
{
Ok((pt, _)) => pt,
Err(err) => panic!("{} invalid: {}", self, err),
}
}
pub fn pt_and_angle(&self, map: &Map) -> (Pt2D, Angle) {
match map
.get_l(self.lane)
.lane_center_pts
.dist_along(self.dist_along)
{
Ok(pair) => pair,
Err(err) => panic!("{} invalid: {}", self, err),
}
}
pub fn equiv_pos(&self, lane: LaneID, map: &Map) -> Position {
self.equiv_pos_for_long_object(lane, Distance::ZERO, map)
}
pub fn equiv_pos_for_long_object(
&self,
other_lane: LaneID,
object_length: Distance,
map: &Map,
) -> Position {
let our_lane = map.get_l(self.lane);
let other_lane = map.get_l(other_lane);
assert_eq!(our_lane.parent, other_lane.parent);
let pl = &other_lane.lane_center_pts;
let pt = self.pt(map);
if let Some((mut dist, _)) = pl.dist_along_of_point(pl.project_pt(pt)) {
if other_lane.dir != our_lane.dir {
dist += object_length;
dist = dist.max(Distance::ZERO).min(other_lane.length());
}
return Position::new(other_lane.id, dist);
}
warn!("equiv_pos of {} for {} messes up", self, other_lane.id);
let len = other_lane.length();
if other_lane.dir == our_lane.dir {
Position::new(other_lane.id, self.dist_along.min(len))
} else {
Position::new(
other_lane.id,
(len - self.dist_along + object_length)
.max(Distance::ZERO)
.min(len),
)
}
}
pub fn min_dist(mut self, dist_along: Distance, map: &Map) -> Option<Position> {
if self.dist_along >= dist_along {
return Some(self);
}
if map.get_l(self.lane).length() < dist_along {
return None;
}
self.dist_along = dist_along;
Some(self)
}
pub fn buffer_dist(mut self, buffer: Distance, map: &Map) -> Option<Position> {
let len = map.get_l(self.lane).length();
if len <= buffer * 2.0 {
return None;
}
self.dist_along = self.dist_along.max(buffer).min(len - buffer);
Some(self)
}
}
#[derive(Clone, Copy, Debug, Eq, Hash, PartialEq, PartialOrd, Ord, Serialize, Deserialize)]
pub enum Traversable {
Lane(LaneID),
Turn(TurnID),
}
impl fmt::Display for Traversable {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
match self {
Traversable::Lane(id) => write!(f, "Traversable::Lane({})", id.0),
Traversable::Turn(id) => write!(
f,
"Traversable::Turn({}, {}, {})",
id.src, id.dst, id.parent
),
}
}
}
impl Traversable {
pub fn as_lane(&self) -> LaneID {
match *self {
Traversable::Lane(id) => id,
Traversable::Turn(_) => panic!("not a lane"),
}
}
pub fn as_turn(&self) -> TurnID {
match *self {
Traversable::Turn(id) => id,
Traversable::Lane(_) => panic!("not a turn"),
}
}
pub fn maybe_turn(&self) -> Option<TurnID> {
match *self {
Traversable::Turn(id) => Some(id),
Traversable::Lane(_) => None,
}
}
pub fn maybe_lane(&self) -> Option<LaneID> {
match *self {
Traversable::Turn(_) => None,
Traversable::Lane(id) => Some(id),
}
}
pub fn get_polyline(self, map: &Map) -> &PolyLine {
match self {
Traversable::Lane(id) => &map.get_l(id).lane_center_pts,
Traversable::Turn(id) => &map.get_t(id).geom,
}
}
pub fn get_zorder(&self, map: &Map) -> isize {
match *self {
Traversable::Lane(id) => map.get_parent(id).zorder,
Traversable::Turn(id) => map.get_i(id.parent).get_zorder(map),
}
}
pub(crate) fn max_speed_along_road(
dr: DirectedRoadID,
max_speed_on_flat_ground: Option<Speed>,
constraints: PathConstraints,
map: &Map,
) -> (Speed, f64) {
let road = map.get_r(dr.id);
let percent_incline = if dr.dir == Direction::Fwd {
road.percent_incline
} else {
-road.percent_incline
};
let base = if constraints == PathConstraints::Bike {
bike_speed_on_incline(max_speed_on_flat_ground.unwrap(), percent_incline)
} else if constraints == PathConstraints::Pedestrian {
walking_speed_on_incline(max_speed_on_flat_ground.unwrap(), percent_incline)
} else {
debug_assert!(max_speed_on_flat_ground.is_none());
road.speed_limit
};
let speed = if let Some(s) = max_speed_on_flat_ground {
base.min(s)
} else {
base
};
(speed, percent_incline)
}
pub(crate) fn max_speed_along_movement(
mvmnt: MovementID,
max_speed_on_flat_ground: Option<Speed>,
_: PathConstraints,
map: &Map,
) -> Speed {
let base = map
.get_r(mvmnt.from.id)
.speed_limit
.min(map.get_r(mvmnt.to.id).speed_limit);
if let Some(s) = max_speed_on_flat_ground {
base.min(s)
} else {
base
}
}
}
pub const MAX_BIKE_SPEED: Speed = Speed::const_meters_per_second(4.4704);
pub const MAX_WALKING_SPEED: Speed = Speed::const_meters_per_second(1.34112);
fn bike_speed_on_incline(max_speed: Speed, percent_incline: f64) -> Speed {
let pct = percent_incline * 100.0;
for (grade, factor) in vec![
(-10.0, 2.2),
(-8.0, 2.0),
(-6.5, 1.9),
(-5.0, 1.7),
(-3.0, 1.4),
(-1.5, 1.2),
(0.0, 1.0),
(1.5, 0.95),
(3.0, 0.85),
(5.0, 0.75),
(6.5, 0.65),
(8.0, 0.55),
(10.0, 0.5),
(11.5, 0.45),
(13.0, 0.4),
] {
if pct <= grade {
return factor * max_speed;
}
}
0.3 * max_speed
}
fn walking_speed_on_incline(max_speed: Speed, percent_incline: f64) -> Speed {
let exp = -3.5 * (percent_incline + 0.05).abs();
let tobler = Speed::km_per_hour(6.0 * std::f64::consts::E.powf(exp));
let result = (tobler / Speed::km_per_hour(5.0)) * max_speed;
if result == Speed::ZERO {
error!(
"walking_speed_on_incline saw an incline of {}. Not going to reduce the speed to 0!",
percent_incline
);
return 0.1 * max_speed;
}
result
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_bike_speed_on_incline() {
let base_speed = MAX_BIKE_SPEED;
assert_approx_eq(
Speed::miles_per_hour(10.0),
bike_speed_on_incline(base_speed, 0.0),
);
assert_approx_eq(
Speed::miles_per_hour(22.0),
bike_speed_on_incline(base_speed, -0.15),
);
assert_approx_eq(
Speed::miles_per_hour(3.0),
bike_speed_on_incline(base_speed, 0.15),
);
}
#[test]
fn test_walking_speed_on_incline() {
let base_speed = MAX_WALKING_SPEED;
assert_approx_eq(
Speed::miles_per_hour(3.0),
walking_speed_on_incline(base_speed, 0.0),
);
assert_approx_eq(
Speed::miles_per_hour(2.54),
walking_speed_on_incline(base_speed, -0.15),
);
assert_approx_eq(
Speed::miles_per_hour(1.79),
walking_speed_on_incline(base_speed, 0.15),
);
}
fn assert_approx_eq(s1: Speed, s2: Speed) {
if (s1.inner_meters_per_second() - s2.inner_meters_per_second()).abs() > 0.1 {
panic!(
"{} != {}",
2.23694 * s1.inner_meters_per_second(),
2.23694 * s2.inner_meters_per_second()
);
}
}
}