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use crate::{DirectedRoadID, Direction, IntersectionID, LaneID, Map, TurnID};
use abstutil::MultiMap;
use geom::{Angle, Distance, PolyLine, Pt2D};
use petgraph::graphmap::UnGraphMap;
use serde::{Deserialize, Serialize};
use std::collections::{BTreeMap, BTreeSet};
#[derive(Clone, Serialize, Deserialize)]
pub struct IntersectionCluster {
pub members: BTreeSet<IntersectionID>,
pub uber_turns: Vec<UberTurn>,
}
#[derive(Debug, Clone, Serialize, Deserialize, PartialEq)]
pub struct UberTurn {
pub path: Vec<TurnID>,
}
impl IntersectionCluster {
pub fn find_all(map: &Map) -> Vec<IntersectionCluster> {
let mut clusters = Vec::new();
let mut seen_intersections = BTreeSet::new();
for i in map.all_intersections() {
if i.is_traffic_signal() && !seen_intersections.contains(&i.id) {
if let Some(members) = IntersectionCluster::autodetect(i.id, map) {
seen_intersections.extend(members.clone());
clusters.push(IntersectionCluster::new(members, map).0);
}
}
}
let mut graph: UnGraphMap<IntersectionID, ()> = UnGraphMap::new();
for from in map.all_roads() {
for (via, _) in &from.complicated_turn_restrictions {
let r = map.get_r(*via);
graph.add_edge(r.src_i, r.dst_i, ());
}
}
for intersections in petgraph::algo::kosaraju_scc(&graph) {
let members: BTreeSet<IntersectionID> = intersections.iter().cloned().collect();
if clusters.iter().any(|ic| ic.members.is_subset(&members)) {
continue;
}
let mut existing: Vec<&mut IntersectionCluster> = clusters
.iter_mut()
.filter(|ic| ic.members.intersection(&members).next().is_some())
.collect();
if existing.is_empty() {
clusters.push(IntersectionCluster::new(members, map).0);
continue;
}
if existing.len() == 1 {
let mut all_members = members;
all_members.extend(existing[0].members.clone());
*existing[0] = IntersectionCluster::new(all_members, map).0;
continue;
}
println!(
"Need a cluster containing {:?} for turn restrictions, but there's more than one \
existing cluster that partly covers it. Union them?",
members
);
return Vec::new();
}
clusters
}
pub fn new(
members: BTreeSet<IntersectionID>,
map: &Map,
) -> (IntersectionCluster, IntersectionCluster) {
let mut entrances = Vec::new();
let mut exits = BTreeSet::new();
for i in &members {
for turn in map.get_turns_in_intersection(*i) {
if turn.between_sidewalks() {
continue;
}
if !members.contains(&map.get_l(turn.id.src).src_i) {
entrances.push(turn.id);
}
if !members.contains(&map.get_l(turn.id.dst).dst_i) {
exits.insert(turn.id);
}
}
}
let mut uber_turns = Vec::new();
for entrance in entrances {
uber_turns.extend(flood(entrance, map, &exits));
}
let mut all_restrictions = Vec::new();
for from in map.all_roads() {
for (via, to) in &from.complicated_turn_restrictions {
all_restrictions.push((from.id, *via, *to));
}
}
let mut illegal = Vec::new();
uber_turns.retain(|ut| {
let mut ok = true;
for pair in ut.path.windows(2) {
let r1 = map.get_l(pair[0].src).parent;
let r2 = map.get_l(pair[0].dst).parent;
let r3 = map.get_l(pair[1].dst).parent;
if all_restrictions.contains(&(r1, r2, r3)) {
ok = false;
break;
}
}
if ok {
true
} else {
illegal.push(ut.clone());
false
}
});
(
IntersectionCluster {
members: members.clone(),
uber_turns,
},
IntersectionCluster {
members,
uber_turns: illegal,
},
)
}
pub fn autodetect(from: IntersectionID, map: &Map) -> Option<BTreeSet<IntersectionID>> {
if !map.get_i(from).is_traffic_signal() {
return None;
}
let threshold = Distance::meters(25.0);
let mut found = BTreeSet::new();
let mut queue = vec![from];
while !queue.is_empty() {
let i = map.get_i(queue.pop().unwrap());
if found.contains(&i.id) {
continue;
}
found.insert(i.id);
for r in &i.roads {
let r = map.get_r(*r);
if r.center_pts.length() > threshold {
continue;
}
let other = if r.src_i == i.id { r.dst_i } else { r.src_i };
if map.get_i(other).is_traffic_signal() {
queue.push(other);
}
}
}
if found.len() > 1 {
Some(found)
} else {
None
}
}
}
fn flood(start: TurnID, map: &Map, exits: &BTreeSet<TurnID>) -> Vec<UberTurn> {
if exits.contains(&start) {
return vec![UberTurn { path: vec![start] }];
}
let mut results = Vec::new();
let mut preds: BTreeMap<TurnID, TurnID> = BTreeMap::new();
let mut queue = vec![start];
while !queue.is_empty() {
let current = queue.pop().unwrap();
for next in map.get_turns_from_lane(current.dst) {
if preds.contains_key(&next.id) {
continue;
}
preds.insert(next.id, current);
if exits.contains(&next.id) {
results.push(UberTurn {
path: trace_back(next.id, &preds),
});
} else {
queue.push(next.id);
}
}
}
results
}
fn trace_back(end: TurnID, preds: &BTreeMap<TurnID, TurnID>) -> Vec<TurnID> {
let mut path = vec![end];
let mut current = end;
loop {
if let Some(prev) = preds.get(¤t) {
path.push(*prev);
current = *prev;
} else {
path.reverse();
return path;
}
}
}
impl UberTurn {
pub fn entry(&self) -> LaneID {
self.path[0].src
}
pub fn exit(&self) -> LaneID {
self.path.last().unwrap().dst
}
pub fn geom(&self, map: &Map) -> PolyLine {
let mut pl = map.get_t(self.path[0]).geom.clone();
let mut first = true;
for pair in self.path.windows(2) {
if !first {
pl = pl.must_extend(map.get_t(pair[0]).geom.clone());
first = false;
}
pl = pl.must_extend(map.get_l(pair[0].dst).lane_center_pts.clone());
pl = pl.must_extend(map.get_t(pair[1]).geom.clone());
}
pl
}
}
pub struct UberTurnGroup {
pub from: DirectedRoadID,
pub to: DirectedRoadID,
pub members: Vec<UberTurn>,
pub geom: PolyLine,
}
impl IntersectionCluster {
pub fn uber_turn_groups(&self, map: &Map) -> Vec<UberTurnGroup> {
let mut groups: MultiMap<(DirectedRoadID, DirectedRoadID), usize> = MultiMap::new();
for (idx, ut) in self.uber_turns.iter().enumerate() {
groups.insert(
(
map.get_l(ut.entry()).get_directed_parent(map),
map.get_l(ut.exit()).get_directed_parent(map),
),
idx,
);
}
let mut result = Vec::new();
for ((from, to), member_indices) in groups.consume() {
let mut members = Vec::new();
let mut polylines = Vec::new();
for idx in member_indices {
polylines.push(self.uber_turns[idx].geom(map));
members.push(self.uber_turns[idx].clone());
}
result.push(UberTurnGroup {
from,
to,
members,
geom: group_geom(polylines),
});
}
result
}
}
impl UberTurnGroup {
pub fn src_center_and_width(&self, map: &Map) -> (PolyLine, Distance) {
let r = map.get_r(self.from.id);
let mut leftmost = Distance::meters(99999.0);
let mut rightmost = Distance::ZERO;
let mut left = Distance::ZERO;
for (l, _, _) in r.lanes_ltr() {
let right = left + map.get_l(l).width;
if self.members.iter().any(|ut| ut.entry() == l) {
leftmost = leftmost.min(left);
rightmost = rightmost.max(right);
}
left = right;
}
let mut pl = map.must_right_shift(r.get_left_side(map), (leftmost + rightmost) / 2.0);
if self.from.dir == Direction::Back {
pl = pl.reversed();
}
(pl.reversed(), rightmost - leftmost)
}
pub fn angle(&self) -> Angle {
self.geom.first_pt().angle_to(self.geom.last_pt())
}
}
fn group_geom(mut polylines: Vec<PolyLine>) -> PolyLine {
let num_pts = polylines[0].points().len();
for pl in &polylines {
if num_pts != pl.points().len() {
return polylines.remove(0);
}
}
let mut pts = Vec::new();
for idx in 0..num_pts {
pts.push(Pt2D::center(
&polylines.iter().map(|pl| pl.points()[idx]).collect(),
));
}
PolyLine::must_new(pts)
}