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use std::cmp::Ordering;
use std::collections::{BinaryHeap, HashMap};
use geom::{Distance, Duration, Speed};
use crate::pathfind::WalkingNode;
use crate::{BuildingID, LaneType, Map, PathConstraints};
#[derive(Clone)]
pub struct WalkingOptions {
pub allow_shoulders: bool,
pub walking_speed: Speed,
}
impl WalkingOptions {
pub fn default() -> WalkingOptions {
WalkingOptions {
allow_shoulders: true,
walking_speed: WalkingOptions::default_speed(),
}
}
pub fn common_speeds() -> Vec<(&'static str, Speed)> {
vec![
("3 mph (average for an adult)", Speed::miles_per_hour(3.0)),
("1 mph (manual wheelchair)", Speed::miles_per_hour(1.0)),
("5 mph (moderate jog)", Speed::miles_per_hour(5.0)),
]
}
pub fn default_speed() -> Speed {
WalkingOptions::common_speeds()[0].1
}
fn cost(&self, dist: Distance) -> Duration {
dist / self.walking_speed
}
}
#[derive(PartialEq, Eq)]
struct Item {
cost: Duration,
node: WalkingNode,
}
impl PartialOrd for Item {
fn partial_cmp(&self, other: &Item) -> Option<Ordering> {
Some(self.cmp(other))
}
}
impl Ord for Item {
fn cmp(&self, other: &Item) -> Ordering {
let ord = other.cost.cmp(&self.cost);
if ord != Ordering::Equal {
return ord;
}
self.node.cmp(&other.node)
}
}
pub fn all_walking_costs_from(
map: &Map,
start: BuildingID,
time_limit: Duration,
opts: WalkingOptions,
) -> HashMap<BuildingID, Duration> {
let start_lane = map.get_l(map.get_b(start).sidewalk_pos.lane());
if start_lane.lane_type == LaneType::Shoulder && !opts.allow_shoulders {
return HashMap::new();
}
let mut queue: BinaryHeap<Item> = BinaryHeap::new();
queue.push(Item {
cost: Duration::ZERO,
node: WalkingNode::closest(map.get_b(start).sidewalk_pos, map),
});
let mut cost_per_node: HashMap<WalkingNode, Duration> = HashMap::new();
while let Some(current) = queue.pop() {
if cost_per_node.contains_key(¤t.node) {
continue;
}
if current.cost > time_limit {
continue;
}
cost_per_node.insert(current.node, current.cost);
let (l, is_dst_i) = match current.node {
WalkingNode::SidewalkEndpoint(l, is_dst_i) => (l, is_dst_i),
_ => unreachable!(),
};
let lane = map.get_l(l);
if opts.allow_shoulders || lane.lane_type != LaneType::Shoulder {
queue.push(Item {
cost: current.cost + opts.cost(lane.length()),
node: WalkingNode::SidewalkEndpoint(lane.id, !is_dst_i),
});
}
for turn in map.get_turns_for(lane.id, PathConstraints::Pedestrian) {
if (turn.id.parent == lane.dst_i) != is_dst_i {
continue;
}
queue.push(Item {
cost: current.cost + opts.cost(turn.geom.length()),
node: WalkingNode::SidewalkEndpoint(
turn.id.dst,
map.get_l(turn.id.dst).dst_i == turn.id.parent,
),
});
}
}
let mut results = HashMap::new();
for b in map.all_buildings() {
if let Some(cost) = cost_per_node.get(&WalkingNode::closest(b.sidewalk_pos, map)) {
let sidewalk_len = map.get_l(b.sidewalk()).length();
let bldg_dist = b.sidewalk_pos.dist_along();
let distance_from_closest_node = if sidewalk_len - bldg_dist <= bldg_dist {
bldg_dist
} else {
sidewalk_len - bldg_dist
};
let total_cost = *cost + distance_from_closest_node / opts.walking_speed;
results.insert(b.id, total_cost);
}
}
results
}