use std::cell::RefCell;
use fast_paths::{deserialize_32, serialize_32, FastGraph, InputGraph, PathCalculator};
use serde::{Deserialize, Serialize};
use thread_local::ThreadLocal;
use abstutil::MultiMap;
use geom::{Distance, Duration};
use crate::pathfind::ch::round;
use crate::pathfind::node_map::{deserialize_nodemap, NodeMap};
use crate::pathfind::uber_turns::{IntersectionCluster, UberTurnV2};
use crate::pathfind::zone_cost;
use crate::{
DirectedRoadID, Direction, DrivingSide, LaneType, Map, MovementID, PathConstraints,
PathRequest, PathV2, RoutingParams, Traversable, TurnType,
};
#[derive(Serialize, Deserialize)]
pub struct VehiclePathfinder {
#[serde(serialize_with = "serialize_32", deserialize_with = "deserialize_32")]
graph: FastGraph,
#[serde(deserialize_with = "deserialize_nodemap")]
nodes: NodeMap<Node>,
uber_turns: Vec<UberTurnV2>,
constraints: PathConstraints,
#[serde(skip_serializing, skip_deserializing)]
path_calc: ThreadLocal<RefCell<PathCalculator>>,
}
#[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Debug, Serialize, Deserialize)]
enum Node {
Road(DirectedRoadID),
UberTurn(usize),
}
impl VehiclePathfinder {
pub fn new(
map: &Map,
constraints: PathConstraints,
seed: Option<&VehiclePathfinder>,
) -> VehiclePathfinder {
let mut nodes = NodeMap::new();
for r in map.all_roads() {
nodes.get_or_insert(Node::Road(DirectedRoadID {
id: r.id,
dir: Direction::Fwd,
}));
nodes.get_or_insert(Node::Road(DirectedRoadID {
id: r.id,
dir: Direction::Back,
}));
}
let mut uber_turns = Vec::new();
for ic in IntersectionCluster::find_all(map) {
for ut in ic.into_v2(map) {
nodes.get_or_insert(Node::UberTurn(uber_turns.len()));
uber_turns.push(ut);
}
}
let input_graph = make_input_graph(map, &nodes, &uber_turns, constraints);
info!(
"Contraction hierarchy input graph for {:?} has {} nodes",
constraints,
abstutil::prettyprint_usize(input_graph.get_num_nodes())
);
let graph = if let Some(seed) = seed {
let node_ordering = seed.graph.get_node_ordering();
fast_paths::prepare_with_order(&input_graph, &node_ordering).unwrap()
} else {
fast_paths::prepare(&input_graph)
};
VehiclePathfinder {
graph,
nodes,
uber_turns,
constraints,
path_calc: ThreadLocal::new(),
}
}
pub fn pathfind(&self, req: PathRequest, map: &Map) -> Option<PathV2> {
assert!(!map.get_l(req.start.lane()).is_walkable());
let mut calc = self
.path_calc
.get_or(|| RefCell::new(fast_paths::create_calculator(&self.graph)))
.borrow_mut();
let raw_path = calc.calc_path(
&self.graph,
self.nodes.get(Node::Road(
map.get_l(req.start.lane()).get_directed_parent(),
)),
self.nodes
.get(Node::Road(map.get_l(req.end.lane()).get_directed_parent())),
)?;
let mut road_steps = Vec::new();
let mut uber_turns = Vec::new();
for node in self.nodes.translate(&raw_path) {
match node {
Node::Road(dr) => {
road_steps.push(dr);
}
Node::UberTurn(ut) => {
for mvmnt in &self.uber_turns[ut].path {
road_steps.push(mvmnt.to);
}
road_steps.pop();
uber_turns.push(self.uber_turns[ut].clone());
}
}
}
let cost = Duration::seconds(raw_path.get_weight() as f64);
Some(PathV2::from_roads(road_steps, req, cost, uber_turns, map))
}
pub fn apply_edits(&mut self, map: &Map) {
let input_graph = make_input_graph(map, &self.nodes, &self.uber_turns, self.constraints);
let node_ordering = self.graph.get_node_ordering();
self.graph = fast_paths::prepare_with_order(&input_graph, &node_ordering).unwrap();
}
}
fn make_input_graph(
map: &Map,
nodes: &NodeMap<Node>,
uber_turns: &Vec<UberTurnV2>,
constraints: PathConstraints,
) -> InputGraph {
let mut input_graph = InputGraph::new();
let mut uber_turn_entrances: MultiMap<DirectedRoadID, usize> = MultiMap::new();
for (idx, ut) in uber_turns.iter().enumerate() {
nodes.get(Node::UberTurn(idx));
if ut
.path
.iter()
.all(|mvmnt| !mvmnt.to.lanes(constraints, map).is_empty())
{
uber_turn_entrances.insert(ut.entry(), idx);
}
}
for r in map.all_roads() {
for dr in r.id.both_directions() {
let from = nodes.get(Node::Road(dr));
if !dr.lanes(constraints, map).is_empty() {
let indices = uber_turn_entrances.get(dr);
if indices.is_empty() {
for mvmnt in map.get_movements_for(dr, constraints) {
input_graph.add_edge(
from,
nodes.get(Node::Road(mvmnt.to)),
round(
vehicle_cost(
mvmnt.from,
mvmnt,
constraints,
map.routing_params(),
map,
) + zone_cost(mvmnt, constraints, map),
),
);
}
} else {
for idx in indices {
let ut = &uber_turns[*idx];
let mut sum_cost = Duration::ZERO;
for mvmnt in &ut.path {
sum_cost += vehicle_cost(
mvmnt.from,
*mvmnt,
constraints,
map.routing_params(),
map,
) + zone_cost(*mvmnt, constraints, map);
}
input_graph.add_edge(
from,
nodes.get(Node::UberTurn(*idx)),
round(sum_cost),
);
input_graph.add_edge(
nodes.get(Node::UberTurn(*idx)),
nodes.get(Node::Road(ut.exit())),
1,
);
}
}
}
}
}
nodes.guarantee_node_ordering(&mut input_graph);
input_graph.freeze();
input_graph
}
pub fn vehicle_cost(
dr: DirectedRoadID,
mvmnt: MovementID,
constraints: PathConstraints,
params: &RoutingParams,
map: &Map,
) -> Duration {
let (mvmnt_length, mvmnt_turn_type) = mvmnt
.get(map)
.map(|m| (m.geom.length(), m.turn_type))
.unwrap_or((Distance::meters(1.0), TurnType::Straight));
let max_speed = match constraints {
PathConstraints::Car | PathConstraints::Bus | PathConstraints::Train => None,
PathConstraints::Bike => Some(crate::MAX_BIKE_SPEED),
PathConstraints::Pedestrian => unreachable!(),
};
let t1 = map.get_r(dr.id).center_pts.length()
/ Traversable::max_speed_along_road(dr, max_speed, constraints, map);
let t2 =
mvmnt_length / Traversable::max_speed_along_movement(mvmnt, max_speed, constraints, map);
let base = match constraints {
PathConstraints::Car | PathConstraints::Train => t1 + t2,
PathConstraints::Bike => {
let lt_penalty = if dr.has_lanes(LaneType::Biking, map) {
params.bike_lane_penalty
} else if dr.has_lanes(LaneType::Bus, map) {
params.bus_lane_penalty
} else {
params.driving_lane_penalty
};
lt_penalty * (t1 + t2)
}
PathConstraints::Bus => {
let lt_penalty = if dr.has_lanes(LaneType::Bus, map) {
1.0
} else {
1.1
};
lt_penalty * (t1 + t2)
}
PathConstraints::Pedestrian => unreachable!(),
};
let unprotected_turn_type = if map.get_config().driving_side == DrivingSide::Right {
TurnType::Left
} else {
TurnType::Right
};
let rank_from = map.get_r(dr.id).get_detailed_rank();
let rank_to = map.get_r(mvmnt.to.id).get_detailed_rank();
if mvmnt_turn_type == unprotected_turn_type
&& rank_from < rank_to
&& map.get_i(mvmnt.parent).is_stop_sign()
{
base + params.unprotected_turn_penalty
} else {
base
}
}