use std::collections::BTreeSet;
use abstutil::{prettyprint_usize, Counter, Parallelism};
use geom::{Circle, Distance, Duration, Pt2D, Time};
use map_gui::render::unzoomed_agent_radius;
use map_gui::tools::{ColorLegend, ColorNetwork};
use map_model::{
BuildingID, Map, OffstreetParking, ParkingLotID, PathConstraints, PathRequest, RoadID,
};
use sim::{ParkingSpot, Scenario, VehicleType};
use widgetry::{
Btn, Checkbox, Drawable, EventCtx, GeomBatch, GfxCtx, HorizontalAlignment, Line, Outcome,
Panel, Text, TextExt, VerticalAlignment, Widget,
};
use crate::app::App;
use crate::layer::{Layer, LayerOutcome};
pub struct Occupancy {
time: Time,
onstreet: bool,
garages: bool,
lots: bool,
private_bldgs: bool,
looking_for_parking: bool,
unzoomed: Drawable,
zoomed: Drawable,
panel: Panel,
}
impl Layer for Occupancy {
fn name(&self) -> Option<&'static str> {
Some("parking occupancy")
}
fn event(
&mut self,
ctx: &mut EventCtx,
app: &mut App,
minimap: &Panel,
) -> Option<LayerOutcome> {
if app.primary.sim.time() != self.time {
*self = Occupancy::new(
ctx,
app,
self.onstreet,
self.garages,
self.lots,
self.private_bldgs,
self.looking_for_parking,
);
}
self.panel.align_above(ctx, minimap);
match self.panel.event(ctx) {
Outcome::Clicked(x) => match x.as_ref() {
"close" => {
return Some(LayerOutcome::Close);
}
_ => unreachable!(),
},
Outcome::Changed => {
*self = Occupancy::new(
ctx,
app,
self.panel.is_checked("On-street spots"),
self.panel.is_checked("Public garages"),
self.panel.is_checked("Parking lots"),
self.panel.is_checked("Private buildings"),
self.panel.is_checked("Cars looking for parking"),
);
self.panel.align_above(ctx, minimap);
}
_ => {}
}
None
}
fn draw(&self, g: &mut GfxCtx, app: &App) {
self.panel.draw(g);
if g.canvas.cam_zoom < app.opts.min_zoom_for_detail {
g.redraw(&self.unzoomed);
} else {
g.redraw(&self.zoomed);
}
}
fn draw_minimap(&self, g: &mut GfxCtx) {
g.redraw(&self.unzoomed);
}
}
impl Occupancy {
pub fn new(
ctx: &mut EventCtx,
app: &App,
onstreet: bool,
garages: bool,
lots: bool,
private_bldgs: bool,
looking_for_parking: bool,
) -> Occupancy {
let mut total_ppl = 0;
let mut has_car = 0;
for p in app.primary.sim.get_all_people() {
total_ppl += 1;
if p.vehicles
.iter()
.any(|v| v.vehicle_type == VehicleType::Car)
{
has_car += 1;
}
}
if app.primary.sim.infinite_parking() {
let panel = Panel::new(Widget::col(vec![
Widget::row(vec![
Widget::draw_svg(ctx, "system/assets/tools/layers.svg"),
"Parking occupancy".draw_text(ctx),
Btn::close(ctx),
]),
Text::from_multiline(vec![
Line(format!(
"{:.0}% of the population owns a car",
if total_ppl == 0 {
0.0
} else {
100.0 * (has_car as f64) / (total_ppl as f64)
}
)),
Line(""),
Line("Parking simulation disabled."),
Line("Every building has unlimited capacity.").secondary(),
])
.draw(ctx),
]))
.aligned(HorizontalAlignment::Right, VerticalAlignment::Center)
.build(ctx);
return Occupancy {
time: app.primary.sim.time(),
onstreet: false,
garages: false,
lots: false,
private_bldgs: false,
looking_for_parking: false,
unzoomed: Drawable::empty(ctx),
zoomed: Drawable::empty(ctx),
panel,
};
}
let mut filled_spots = Counter::new();
let mut avail_spots = Counter::new();
let mut keys = BTreeSet::new();
let mut public_filled = 0;
let mut public_avail = 0;
let mut private_filled = 0;
let mut private_avail = 0;
let (all_filled_spots, all_avail_spots) = app.primary.sim.get_all_parking_spots();
for (input, public_counter, private_counter, spots) in vec![
(
all_filled_spots,
&mut public_filled,
&mut private_filled,
&mut filled_spots,
),
(
all_avail_spots,
&mut public_avail,
&mut private_avail,
&mut avail_spots,
),
] {
for spot in input {
match spot {
ParkingSpot::Onstreet(_, _) => {
if !onstreet {
continue;
}
*public_counter += 1;
}
ParkingSpot::Offstreet(b, _) => {
if let OffstreetParking::PublicGarage(_, _) =
app.primary.map.get_b(b).parking
{
if !garages {
continue;
}
*public_counter += 1;
} else {
if !private_bldgs {
continue;
}
*private_counter += 1;
}
}
ParkingSpot::Lot(_, _) => {
if !lots {
continue;
}
*public_counter += 1;
}
}
let loc = Loc::new(spot, &app.primary.map);
keys.insert(loc);
spots.inc(loc);
}
}
let panel = Panel::new(Widget::col(vec![
Widget::row(vec![
Widget::draw_svg(ctx, "system/assets/tools/layers.svg"),
"Parking occupancy".draw_text(ctx),
Btn::close(ctx),
]),
Text::from_multiline(vec![
Line(format!(
"{:.0}% of the population owns a car",
if total_ppl == 0 {
0.0
} else {
100.0 * (has_car as f64) / (total_ppl as f64)
}
)),
Line(format!(
"{} / {} public spots filled",
prettyprint_usize(public_filled),
prettyprint_usize(public_filled + public_avail)
)),
Line(format!(
"{} / {} private spots filled",
prettyprint_usize(private_filled),
prettyprint_usize(private_filled + private_avail)
)),
])
.draw(ctx),
Widget::row(vec![
Checkbox::switch(ctx, "On-street spots", None, onstreet),
Checkbox::switch(ctx, "Parking lots", None, lots),
])
.evenly_spaced(),
Widget::row(vec![
Checkbox::switch(ctx, "Public garages", None, garages),
Checkbox::switch(ctx, "Private buildings", None, private_bldgs),
])
.evenly_spaced(),
Checkbox::colored(
ctx,
"Cars looking for parking",
app.cs.parking_trip,
looking_for_parking,
),
ColorLegend::gradient(ctx, &app.cs.good_to_bad_red, vec!["0%", "100%"]),
]))
.aligned(HorizontalAlignment::Right, VerticalAlignment::Center)
.build(ctx);
let mut colorer = ColorNetwork::new(app);
for loc in keys {
let open = avail_spots.get(loc);
let closed = filled_spots.get(loc);
let percent = (closed as f64) / ((open + closed) as f64);
let color = app.cs.good_to_bad_red.eval(percent);
match loc {
Loc::Road(r) => colorer.add_r(r, color),
Loc::Bldg(b) => colorer.add_b(b, color),
Loc::Lot(pl) => colorer.add_pl(pl, color),
}
}
if looking_for_parking {
let car_circle = Circle::new(
Pt2D::new(0.0, 0.0),
unzoomed_agent_radius(Some(VehicleType::Car)),
)
.to_polygon();
for a in app.primary.sim.get_unzoomed_agents(&app.primary.map) {
if a.parking {
colorer.unzoomed.push(
app.cs.parking_trip.alpha(0.8),
car_circle.translate(a.pos.x(), a.pos.y()),
);
}
}
}
let (unzoomed, zoomed) = colorer.build(ctx);
Occupancy {
time: app.primary.sim.time(),
onstreet,
garages,
lots,
private_bldgs,
looking_for_parking,
unzoomed,
zoomed,
panel,
}
}
}
#[derive(PartialEq, Eq, PartialOrd, Ord, Clone, Copy)]
enum Loc {
Road(RoadID),
Bldg(BuildingID),
Lot(ParkingLotID),
}
impl Loc {
fn new(spot: ParkingSpot, map: &Map) -> Loc {
match spot {
ParkingSpot::Onstreet(l, _) => Loc::Road(map.get_l(l).parent),
ParkingSpot::Offstreet(b, _) => Loc::Bldg(b),
ParkingSpot::Lot(pl, _) => Loc::Lot(pl),
}
}
}
pub struct Efficiency {
time: Time,
unzoomed: Drawable,
zoomed: Drawable,
panel: Panel,
}
impl Layer for Efficiency {
fn name(&self) -> Option<&'static str> {
Some("parking efficiency")
}
fn event(
&mut self,
ctx: &mut EventCtx,
app: &mut App,
minimap: &Panel,
) -> Option<LayerOutcome> {
if app.primary.sim.time() != self.time {
*self = Efficiency::new(ctx, app);
}
self.panel.align_above(ctx, minimap);
match self.panel.event(ctx) {
Outcome::Clicked(x) => match x.as_ref() {
"close" => {
return Some(LayerOutcome::Close);
}
_ => unreachable!(),
},
_ => {}
}
None
}
fn draw(&self, g: &mut GfxCtx, app: &App) {
self.panel.draw(g);
if g.canvas.cam_zoom < app.opts.min_zoom_for_detail {
g.redraw(&self.unzoomed);
} else {
g.redraw(&self.zoomed);
}
}
fn draw_minimap(&self, g: &mut GfxCtx) {
g.redraw(&self.unzoomed);
}
}
impl Efficiency {
pub fn new(ctx: &mut EventCtx, app: &App) -> Efficiency {
let panel = Panel::new(Widget::col(vec![
Widget::row(vec![
Widget::draw_svg(ctx, "system/assets/tools/layers.svg"),
"Parking efficiency".draw_text(ctx),
Btn::close(ctx),
]),
Text::from(Line("How far away are people parked? (minutes)").secondary())
.wrap_to_pct(ctx, 15)
.draw(ctx),
ColorLegend::gradient(
ctx,
&app.cs.good_to_bad_red,
vec!["0", "3", "6", "10+"],
),
]))
.aligned(HorizontalAlignment::Right, VerticalAlignment::Center)
.build(ctx);
let map = &app.primary.map;
let (unzoomed, zoomed) = ctx.loading_screen("measure parking efficiency", |ctx, timer| {
let mut unzoomed = GeomBatch::new();
let mut zoomed = GeomBatch::new();
timer.start("gather requests");
let requests: Vec<PathRequest> = app
.primary
.sim
.all_parked_car_positions(map)
.into_iter()
.map(|(start, end)| PathRequest {
start,
end,
constraints: PathConstraints::Pedestrian,
})
.collect();
timer.stop("gather requests");
for (car_pt, dist) in timer
.parallelize("calculate paths", Parallelism::Fastest, requests, |req| {
let car_pt = req.start.pt(map);
if req.start == req.end {
Some((car_pt, Distance::ZERO))
} else {
map.pathfind(req)
.ok()
.map(|path| (car_pt, path.total_length()))
}
})
.into_iter()
.flatten()
{
let time = dist / Scenario::max_ped_speed();
let color = app
.cs
.good_to_bad_red
.eval((time / Duration::minutes(10)).min(1.0));
unzoomed.push(
color,
Circle::new(car_pt, Distance::meters(5.0)).to_polygon(),
);
zoomed.push(
color.alpha(0.5),
Circle::new(car_pt, Distance::meters(2.0)).to_polygon(),
);
}
(ctx.upload(unzoomed), ctx.upload(zoomed))
});
Efficiency {
time: app.primary.sim.time(),
unzoomed,
zoomed,
panel,
}
}
}