use std::collections::{BTreeMap, BTreeSet, VecDeque};
use serde::{Deserialize, Serialize};
use abstutil::Counter;
use geom::{Duration, Time};
use map_model::{
BusRouteID, BusStopID, CompressedMovementID, IntersectionID, LaneID, Map, MovementID,
ParkingLotID, Path, PathRequest, RoadID, Traversable, TurnID, TurnType,
};
use crate::{
AgentID, AgentType, AlertLocation, CarID, Event, ParkingSpot, TripID, TripMode, TripPhaseType,
};
#[derive(Clone, Serialize, Deserialize)]
pub struct Analytics {
pub road_thruput: TimeSeriesCount<RoadID>,
pub intersection_thruput: TimeSeriesCount<IntersectionID>,
pub traffic_signal_thruput: TimeSeriesCount<CompressedMovementID>,
pub demand: BTreeMap<MovementID, usize>,
pub bus_arrivals: Vec<(Time, CarID, BusRouteID, BusStopID)>,
pub passengers_boarding: BTreeMap<BusStopID, Vec<(Time, BusRouteID, Duration)>>,
pub passengers_alighting: BTreeMap<BusStopID, Vec<(Time, BusRouteID)>>,
pub started_trips: BTreeMap<TripID, Time>,
pub finished_trips: Vec<(Time, TripID, TripMode, Option<Duration>)>,
pub problems_per_trip: BTreeMap<TripID, Vec<(Time, Problem)>>,
pub trip_log: Vec<(Time, TripID, Option<PathRequest>, TripPhaseType)>,
pub intersection_delays: BTreeMap<IntersectionID, Vec<(u8, Time, Duration, AgentType)>>,
pub parking_lane_changes: BTreeMap<LaneID, Vec<(Time, bool)>>,
pub parking_lot_changes: BTreeMap<ParkingLotID, Vec<(Time, bool)>>,
pub(crate) alerts: Vec<(Time, AlertLocation, String)>,
record_anything: bool,
}
#[derive(Clone, Debug, PartialEq, Serialize, Deserialize)]
pub enum Problem {
IntersectionDelay(IntersectionID, Duration),
ComplexIntersectionCrossing(IntersectionID),
ArterialIntersectionCrossing(TurnID),
OvertakeDesired(Traversable),
}
impl Analytics {
pub fn new(record_anything: bool) -> Analytics {
Analytics {
road_thruput: TimeSeriesCount::new(),
intersection_thruput: TimeSeriesCount::new(),
traffic_signal_thruput: TimeSeriesCount::new(),
demand: BTreeMap::new(),
bus_arrivals: Vec::new(),
passengers_boarding: BTreeMap::new(),
passengers_alighting: BTreeMap::new(),
started_trips: BTreeMap::new(),
finished_trips: Vec::new(),
problems_per_trip: BTreeMap::new(),
trip_log: Vec::new(),
intersection_delays: BTreeMap::new(),
parking_lane_changes: BTreeMap::new(),
parking_lot_changes: BTreeMap::new(),
alerts: Vec::new(),
record_anything,
}
}
pub fn event(&mut self, ev: Event, time: Time, map: &Map) {
if !self.record_anything {
return;
}
if let Event::AgentEntersTraversable(a, _, to, passengers) = ev {
match to {
Traversable::Lane(l) => {
self.road_thruput
.record(time, map.get_l(l).parent, a.to_type(), 1);
if let Some(n) = passengers {
self.road_thruput.record(
time,
map.get_l(l).parent,
AgentType::TransitRider,
n,
);
}
}
Traversable::Turn(t) => {
self.intersection_thruput
.record(time, t.parent, a.to_type(), 1);
if let Some(n) = passengers {
self.intersection_thruput.record(
time,
t.parent,
AgentType::TransitRider,
n,
);
}
if let Some(id) = map.get_movement(t) {
*self.demand.entry(id).or_insert(0) -= 1;
let m = map.get_traffic_signal(t.parent).compressed_id(t);
self.traffic_signal_thruput.record(time, m, a.to_type(), 1);
if let Some(n) = passengers {
self.traffic_signal_thruput
.record(time, m, AgentType::TransitRider, n);
}
}
}
};
}
match ev {
Event::PersonLeavesMap(_, Some(a), i) => {
self.intersection_thruput.record(time, i, a.to_type(), 1);
}
Event::PersonEntersMap(_, a, i) => {
self.intersection_thruput.record(time, i, a.to_type(), 1);
}
_ => {}
}
if let Event::BusArrivedAtStop(bus, route, stop) = ev {
self.bus_arrivals.push((time, bus, route, stop));
}
if let Event::PassengerBoardsTransit(_, _, route, stop, waiting) = ev {
self.passengers_boarding
.entry(stop)
.or_insert_with(Vec::new)
.push((time, route, waiting));
}
if let Event::PassengerAlightsTransit(_, _, route, stop) = ev {
self.passengers_alighting
.entry(stop)
.or_insert_with(Vec::new)
.push((time, route));
}
if let Event::TripPhaseStarting(id, _, _, _) = ev {
self.started_trips.entry(id).or_insert(time);
}
if let Event::TripFinished {
trip,
mode,
total_time,
..
} = ev
{
self.finished_trips
.push((time, trip, mode, Some(total_time)));
} else if let Event::TripCancelled(id, mode) = ev {
self.started_trips.entry(id).or_insert(time);
self.finished_trips.push((time, id, mode, None));
}
if let Event::IntersectionDelayMeasured(trip_id, turn_id, agent, delay) = ev {
let threshold = match agent {
AgentID::Car(_) => Duration::seconds(30.0),
AgentID::Pedestrian(_) => Duration::seconds(15.0),
AgentID::BusPassenger(_, _) => Duration::hours(24),
};
if delay > threshold {
self.problems_per_trip
.entry(trip_id)
.or_insert_with(Vec::new)
.push((time, Problem::IntersectionDelay(turn_id.parent, delay)));
}
if map.get_t(turn_id).turn_type != TurnType::SharedSidewalkCorner {
if let Some(ts) = map.maybe_get_traffic_signal(turn_id.parent) {
self.intersection_delays
.entry(turn_id.parent)
.or_insert_with(Vec::new)
.push((ts.compressed_id(turn_id).idx, time, delay, agent.to_type()));
}
}
}
if let Event::CarReachedParkingSpot(_, spot) = ev {
if let ParkingSpot::Onstreet(l, _) = spot {
self.parking_lane_changes
.entry(l)
.or_insert_with(Vec::new)
.push((time, true));
} else if let ParkingSpot::Lot(pl, _) = spot {
self.parking_lot_changes
.entry(pl)
.or_insert_with(Vec::new)
.push((time, true));
}
}
if let Event::CarLeftParkingSpot(_, spot) = ev {
if let ParkingSpot::Onstreet(l, _) = spot {
self.parking_lane_changes
.entry(l)
.or_insert_with(Vec::new)
.push((time, false));
} else if let ParkingSpot::Lot(pl, _) = spot {
self.parking_lot_changes
.entry(pl)
.or_insert_with(Vec::new)
.push((time, false));
}
}
if let Event::AgentEntersTraversable(a, Some(trip), Traversable::Turn(t), _) = ev {
if a.to_type() == AgentType::Bike && map.get_i(t.parent).roads.len() > 4 {
self.problems_per_trip
.entry(trip)
.or_insert_with(Vec::new)
.push((time, Problem::ComplexIntersectionCrossing(t.parent)));
}
}
if let Event::AgentEntersTraversable(a, Some(trip), Traversable::Turn(t), _) = ev {
let turn = map.get_t(t);
if a.to_type() == AgentType::Pedestrian && turn.is_crossing_arterial_intersection(map) {
self.problems_per_trip
.entry(trip)
.or_insert_with(Vec::new)
.push((time, Problem::ArterialIntersectionCrossing(turn.id)));
}
}
match ev {
Event::TripPhaseStarting(id, _, maybe_req, phase_type) => {
self.trip_log.push((time, id, maybe_req, phase_type));
}
Event::TripCancelled(id, _) => {
self.trip_log
.push((time, id, None, TripPhaseType::Cancelled));
}
Event::TripFinished { trip, .. } => {
self.trip_log
.push((time, trip, None, TripPhaseType::Finished));
}
Event::PathAmended(path) => {
self.record_demand(&path, map);
}
Event::Alert(loc, msg) => {
self.alerts.push((time, loc, msg));
}
Event::ProblemEncountered(trip, problem) => {
self.problems_per_trip
.entry(trip)
.or_insert_with(Vec::new)
.push((time, problem));
}
_ => {}
}
}
pub fn record_demand(&mut self, path: &Path, map: &Map) {
for step in path.get_steps() {
if let Traversable::Turn(t) = step.as_traversable() {
if let Some(id) = map.get_movement(t) {
*self.demand.entry(id).or_insert(0) += 1;
}
}
}
}
pub fn finished_trip_time(&self, trip: TripID) -> Option<Duration> {
for (_, id, _, maybe_dt) in &self.finished_trips {
if *id == trip {
return *maybe_dt;
}
}
None
}
pub fn both_finished_trips(
&self,
now: Time,
before: &Analytics,
) -> Vec<(TripID, Duration, Duration, TripMode)> {
let mut a = BTreeMap::new();
for (t, id, _, maybe_dt) in &self.finished_trips {
if *t > now {
break;
}
if let Some(dt) = maybe_dt {
a.insert(*id, *dt);
}
}
let mut results = Vec::new();
for (t, id, mode, maybe_dt) in &before.finished_trips {
if *t > now {
break;
}
if let Some(dt) = maybe_dt {
if let Some(dt1) = a.remove(id) {
results.push((*id, *dt, dt1, *mode));
}
}
}
results
}
pub fn get_trip_phases(&self, trip: TripID, map: &Map) -> Vec<TripPhase> {
let mut phases: Vec<TripPhase> = Vec::new();
for (t, id, maybe_req, phase_type) in &self.trip_log {
if *id != trip {
continue;
}
if let Some(ref mut last) = phases.last_mut() {
last.end_time = Some(*t);
}
if *phase_type == TripPhaseType::Finished || *phase_type == TripPhaseType::Cancelled {
break;
}
phases.push(TripPhase {
start_time: *t,
end_time: None,
path: maybe_req.clone().and_then(|req| map.pathfind(req).ok()),
has_path_req: maybe_req.is_some(),
phase_type: *phase_type,
})
}
phases
}
pub fn get_all_trip_phases(&self) -> BTreeMap<TripID, Vec<TripPhase>> {
let mut trips = BTreeMap::new();
for (t, id, maybe_req, phase_type) in &self.trip_log {
let phases: &mut Vec<TripPhase> = trips.entry(*id).or_insert_with(Vec::new);
if let Some(ref mut last) = phases.last_mut() {
last.end_time = Some(*t);
}
if *phase_type == TripPhaseType::Finished {
continue;
}
if *phase_type == TripPhaseType::Cancelled {
trips.remove(id);
continue;
}
phases.push(TripPhase {
start_time: *t,
end_time: None,
path: None,
has_path_req: maybe_req.is_some(),
phase_type: *phase_type,
})
}
trips
}
pub fn active_agents(&self, now: Time) -> Vec<(Time, usize)> {
let mut starts_stops: Vec<(Time, bool)> = Vec::new();
for t in self.started_trips.values() {
if *t <= now {
starts_stops.push((*t, false));
}
}
for (t, _, _, _) in &self.finished_trips {
if *t > now {
break;
}
starts_stops.push((*t, true));
}
starts_stops.sort();
let mut pts = Vec::new();
let mut cnt = 0;
let mut last_t = Time::START_OF_DAY;
for (t, ended) in starts_stops {
if t != last_t {
pts.push((last_t, cnt));
}
last_t = t;
if ended {
if cnt == 0 {
panic!("active_agents at {} has more ended trips than started", t);
}
cnt -= 1;
} else {
cnt += 1;
}
}
pts.push((last_t, cnt));
if last_t != now {
pts.push((now, cnt));
}
pts
}
pub fn parking_lane_availability(
&self,
now: Time,
l: LaneID,
capacity: usize,
) -> Vec<(Time, usize)> {
if let Some(changes) = self.parking_lane_changes.get(&l) {
Analytics::parking_spot_availability(now, changes, capacity)
} else {
vec![(Time::START_OF_DAY, capacity), (now, capacity)]
}
}
pub fn parking_lot_availability(
&self,
now: Time,
pl: ParkingLotID,
capacity: usize,
) -> Vec<(Time, usize)> {
if let Some(changes) = self.parking_lot_changes.get(&pl) {
Analytics::parking_spot_availability(now, changes, capacity)
} else {
vec![(Time::START_OF_DAY, capacity), (now, capacity)]
}
}
fn parking_spot_availability(
now: Time,
changes: &[(Time, bool)],
capacity: usize,
) -> Vec<(Time, usize)> {
let mut pts = Vec::new();
let mut cnt = capacity;
let mut last_t = Time::START_OF_DAY;
for (t, filled) in changes {
if *t > now {
break;
}
if *t != last_t {
pts.push((last_t, cnt));
}
last_t = *t;
if *filled {
if cnt == 0 {
panic!("parking_spot_availability at {} went below 0", t);
}
cnt -= 1;
} else {
cnt += 1;
}
}
pts.push((last_t, cnt));
if last_t != now {
pts.push((now, cnt));
}
pts
}
}
impl Default for Analytics {
fn default() -> Analytics {
Analytics::new(false)
}
}
#[derive(Debug)]
pub struct TripPhase {
pub start_time: Time,
pub end_time: Option<Time>,
pub path: Option<Path>,
pub has_path_req: bool,
pub phase_type: TripPhaseType,
}
#[derive(Clone, Serialize, Deserialize)]
pub struct TimeSeriesCount<X: Ord + Clone> {
pub counts: BTreeMap<(X, AgentType, usize), usize>,
pub raw: Vec<(Time, AgentType, X)>,
}
impl<X: Ord + Clone> TimeSeriesCount<X> {
fn new() -> TimeSeriesCount<X> {
TimeSeriesCount {
counts: BTreeMap::new(),
raw: Vec::new(),
}
}
fn record(&mut self, time: Time, id: X, agent_type: AgentType, count: usize) {
if false {
for _ in 0..count {
self.raw.push((time, agent_type, id.clone()));
}
}
*self
.counts
.entry((id, agent_type, time.get_hours()))
.or_insert(0) += count;
}
pub fn total_for(&self, id: X) -> usize {
self.total_for_with_agent_types(id, AgentType::all().into_iter().collect())
}
pub fn total_for_with_agent_types(&self, id: X, agent_types: BTreeSet<AgentType>) -> usize {
let mut cnt = 0;
for agent_type in agent_types {
for hour in 0..24 {
cnt += self
.counts
.get(&(id.clone(), agent_type, hour))
.cloned()
.unwrap_or(0);
}
}
cnt
}
pub fn total_for_by_time(&self, id: X, now: Time) -> usize {
let mut cnt = 0;
for agent_type in AgentType::all() {
for hour in 0..=now.get_hours() {
cnt += self
.counts
.get(&(id.clone(), agent_type, hour))
.cloned()
.unwrap_or(0);
}
}
cnt
}
pub fn all_total_counts(&self, agent_types: &BTreeSet<AgentType>) -> Counter<X> {
let mut cnt = Counter::new();
for ((id, agent_type, _), value) in &self.counts {
if agent_types.contains(&agent_type) {
cnt.add(id.clone(), *value);
}
}
cnt
}
pub fn count_per_hour(&self, id: X, time: Time) -> Vec<(AgentType, Vec<(Time, usize)>)> {
let hour = time.get_hours();
let mut results = Vec::new();
for agent_type in AgentType::all() {
let mut pts = Vec::new();
for hour in 0..=hour {
let cnt = self
.counts
.get(&(id.clone(), agent_type, hour))
.cloned()
.unwrap_or(0);
pts.push((Time::START_OF_DAY + Duration::hours(hour), cnt));
pts.push((Time::START_OF_DAY + Duration::hours(hour + 1), cnt));
}
pts.pop();
results.push((agent_type, pts));
}
results
}
pub fn raw_throughput(&self, now: Time, id: X) -> Vec<(AgentType, Vec<(Time, usize)>)> {
let window_size = Duration::hours(1);
let mut pts_per_type: BTreeMap<AgentType, Vec<(Time, usize)>> = BTreeMap::new();
let mut windows_per_type: BTreeMap<AgentType, Window> = BTreeMap::new();
for agent_type in AgentType::all() {
pts_per_type.insert(agent_type, vec![(Time::START_OF_DAY, 0)]);
windows_per_type.insert(agent_type, Window::new(window_size));
}
for (t, agent_type, x) in &self.raw {
if *x != id {
continue;
}
if *t > now {
break;
}
let count = windows_per_type.get_mut(agent_type).unwrap().add(*t);
pts_per_type.get_mut(agent_type).unwrap().push((*t, count));
}
for (agent_type, pts) in pts_per_type.iter_mut() {
let mut window = windows_per_type.remove(agent_type).unwrap();
let t = (pts.last().unwrap().0 + window_size + Duration::seconds(0.1)).min(now);
if pts.last().unwrap().0 != t {
pts.push((t, window.count(t)));
}
if pts.last().unwrap().0 != now {
pts.push((now, window.count(now)));
}
}
pts_per_type.into_iter().collect()
}
}
pub struct Window {
times: VecDeque<Time>,
window_size: Duration,
}
impl Window {
pub fn new(window_size: Duration) -> Window {
Window {
times: VecDeque::new(),
window_size,
}
}
pub fn add(&mut self, time: Time) -> usize {
self.times.push_back(time);
self.count(time)
}
pub fn count(&mut self, end: Time) -> usize {
while !self.times.is_empty() && end - *self.times.front().unwrap() > self.window_size {
self.times.pop_front();
}
self.times.len()
}
}