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use std::cell::RefCell;
use std::collections::HashMap;
use serde::{Deserialize, Serialize};
use thread_local::ThreadLocal;
use abstutil::{Timer, VecMap};
use geom::Duration;
use crate::pathfind::engine::CreateEngine;
use crate::pathfind::vehicles::VehiclePathfinder;
use crate::pathfind::walking::SidewalkPathfinder;
use crate::{
BusRouteID, BusStopID, DirectedRoadID, Map, PathConstraints, PathRequest, PathV2, Position,
RoutingParams,
};
#[derive(Serialize, Deserialize)]
pub struct Pathfinder {
car_graph: VehiclePathfinder,
bike_graph: VehiclePathfinder,
bus_graph: VehiclePathfinder,
train_graph: VehiclePathfinder,
walking_graph: SidewalkPathfinder,
walking_with_transit_graph: SidewalkPathfinder,
params: RoutingParams,
#[serde(skip_serializing, skip_deserializing)]
cached_alternatives: ThreadLocal<RefCell<VecMap<(PathConstraints, RoutingParams), Pathfinder>>>,
}
impl Clone for Pathfinder {
fn clone(&self) -> Self {
Self {
car_graph: self.car_graph.clone(),
bike_graph: self.bike_graph.clone(),
bus_graph: self.bus_graph.clone(),
train_graph: self.train_graph.clone(),
walking_graph: self.walking_graph.clone(),
walking_with_transit_graph: self.walking_with_transit_graph.clone(),
params: self.params.clone(),
cached_alternatives: ThreadLocal::new(),
}
}
}
impl Pathfinder {
pub fn empty() -> Pathfinder {
Pathfinder {
car_graph: VehiclePathfinder::empty(),
bike_graph: VehiclePathfinder::empty(),
bus_graph: VehiclePathfinder::empty(),
train_graph: VehiclePathfinder::empty(),
walking_graph: SidewalkPathfinder::empty(),
walking_with_transit_graph: SidewalkPathfinder::empty(),
params: RoutingParams::default(),
cached_alternatives: ThreadLocal::new(),
}
}
pub fn new(
map: &Map,
params: RoutingParams,
engine: CreateEngine,
timer: &mut Timer,
) -> Pathfinder {
timer.start("prepare pathfinding for cars");
let car_graph = VehiclePathfinder::new(map, PathConstraints::Car, ¶ms, &engine);
timer.stop("prepare pathfinding for cars");
timer.start("prepare pathfinding for bikes");
let bike_graph = VehiclePathfinder::new(map, PathConstraints::Bike, ¶ms, &engine);
timer.stop("prepare pathfinding for bikes");
timer.start("prepare pathfinding for buses");
let bus_graph = VehiclePathfinder::new(
map,
PathConstraints::Bus,
¶ms,
&car_graph.engine.reuse_ordering(),
);
timer.stop("prepare pathfinding for buses");
timer.start("prepare pathfinding for trains");
let train_graph = VehiclePathfinder::new(
map,
PathConstraints::Train,
¶ms,
&CreateEngine::Dijkstra,
);
timer.stop("prepare pathfinding for trains");
timer.start("prepare pathfinding for pedestrians");
let walking_graph = SidewalkPathfinder::new(map, None, &engine);
timer.stop("prepare pathfinding for pedestrians");
timer.start("prepare pathfinding for pedestrians using transit");
let walking_with_transit_graph =
SidewalkPathfinder::new(map, Some((&bus_graph, &train_graph)), &engine);
timer.stop("prepare pathfinding for pedestrians using transit");
Pathfinder {
car_graph,
bike_graph,
bus_graph,
train_graph,
walking_graph,
walking_with_transit_graph,
params,
cached_alternatives: ThreadLocal::new(),
}
}
pub fn new_for_one_mode(
map: &Map,
params: RoutingParams,
engine: CreateEngine,
constraints: PathConstraints,
timer: &mut Timer,
) -> Pathfinder {
let mut p = Pathfinder::empty();
timer.start("prepare pathfinding for just one mode");
match constraints {
PathConstraints::Pedestrian => {
p.walking_graph = SidewalkPathfinder::new(map, None, &engine);
}
PathConstraints::Car => {
p.car_graph = VehiclePathfinder::new(map, constraints, ¶ms, &engine);
}
PathConstraints::Bike => {
p.bike_graph = VehiclePathfinder::new(map, constraints, ¶ms, &engine);
}
PathConstraints::Bus => {
p.bus_graph = VehiclePathfinder::new(map, constraints, ¶ms, &engine);
}
PathConstraints::Train => {
p.train_graph = VehiclePathfinder::new(map, constraints, ¶ms, &engine);
}
}
timer.stop("prepare pathfinding for just one mode");
p.params = params;
p
}
pub fn pathfind(&self, req: PathRequest, map: &Map) -> Option<PathV2> {
self.pathfind_with_params(req, map.routing_params(), false, map)
}
pub fn pathfind_with_params(
&self,
req: PathRequest,
params: &RoutingParams,
cache_custom: bool,
map: &Map,
) -> Option<PathV2> {
let constraints = req.constraints;
if params == &self.params {
return match constraints {
PathConstraints::Pedestrian => self.walking_graph.pathfind(req, map),
PathConstraints::Car => self.car_graph.pathfind(req, map),
PathConstraints::Bike => self.bike_graph.pathfind(req, map),
PathConstraints::Bus => self.bus_graph.pathfind(req, map),
PathConstraints::Train => self.train_graph.pathfind(req, map),
};
}
if let Some(alt) = self
.cached_alternatives
.get_or(|| RefCell::new(VecMap::new()))
.borrow()
.get(&(constraints, params.clone()))
{
return alt.pathfind_with_params(req, params, false, map);
}
let mut timer = Timer::new(format!("Pathfinding slowly for {} with custom params", req));
let tmp_pathfinder = Pathfinder::new_for_one_mode(
map,
params.clone(),
CreateEngine::Dijkstra,
constraints,
&mut timer,
);
let result = tmp_pathfinder.pathfind_with_params(req, params, false, map);
if cache_custom {
self.cached_alternatives
.get_or(|| RefCell::new(VecMap::new()))
.borrow_mut()
.push((constraints, params.clone()), tmp_pathfinder);
}
result
}
pub fn all_costs_from(
&self,
req: PathRequest,
map: &Map,
) -> Option<(Duration, HashMap<DirectedRoadID, Duration>)> {
let req_cost = self.pathfind(req.clone(), map)?.get_cost();
let all_costs = match req.constraints {
PathConstraints::Pedestrian => self.walking_graph.all_costs_from(req.start, map),
PathConstraints::Car => self.car_graph.all_costs_from(req.start, map),
PathConstraints::Bike => self.bike_graph.all_costs_from(req.start, map),
PathConstraints::Bus | PathConstraints::Train => unreachable!(),
};
Some((req_cost, all_costs))
}
pub fn should_use_transit(
&self,
map: &Map,
start: Position,
end: Position,
) -> Option<(BusStopID, Option<BusStopID>, BusRouteID)> {
self.walking_with_transit_graph
.should_use_transit(map, start, end)
}
pub fn apply_edits(&mut self, map: &Map, timer: &mut Timer) {
timer.start("apply edits to car pathfinding");
self.car_graph.apply_edits(map);
timer.stop("apply edits to car pathfinding");
timer.start("apply edits to bike pathfinding");
self.bike_graph.apply_edits(map);
timer.stop("apply edits to bike pathfinding");
timer.start("apply edits to bus pathfinding");
self.bus_graph.apply_edits(map);
timer.stop("apply edits to bus pathfinding");
timer.start("apply edits to train pathfinding");
self.train_graph.apply_edits(map);
timer.stop("apply edits to train pathfinding");
timer.start("apply edits to pedestrian pathfinding");
self.walking_graph.apply_edits(map, None);
timer.stop("apply edits to pedestrian pathfinding");
timer.start("apply edits to pedestrian using transit pathfinding");
self.walking_with_transit_graph
.apply_edits(map, Some((&self.bus_graph, &self.train_graph)));
timer.stop("apply edits to pedestrian using transit pathfinding");
}
}