use std::cell::RefCell;
use std::collections::HashMap;
use geom::{Angle, ArrowCap, Distance, Line, PolyLine, Polygon, Pt2D};
use map_model::{Direction, DrivingSide, Lane, LaneID, LaneType, Map, Road, RoadID, TurnID};
use widgetry::{Drawable, GeomBatch, GfxCtx, Prerender, RewriteColor};
use crate::render::{DrawOptions, Renderable, OUTLINE_THICKNESS};
use crate::{AppLike, ID};
pub struct DrawLane {
pub id: LaneID,
pub polygon: Polygon,
zorder: isize,
draw_default: RefCell<Option<Drawable>>,
}
impl DrawLane {
pub fn new(lane: &Lane, map: &Map) -> DrawLane {
DrawLane {
id: lane.id,
polygon: lane.lane_center_pts.make_polygons(lane.width),
zorder: map.get_r(lane.parent).zorder,
draw_default: RefCell::new(None),
}
}
pub fn render<P: AsRef<Prerender>>(&self, prerender: &P, app: &dyn AppLike) -> GeomBatch {
let map = app.map();
let lane = map.get_l(self.id);
let road = map.get_r(lane.parent);
let mut batch = GeomBatch::new();
if !lane.is_light_rail() {
batch.push(
app.cs()
.zoomed_road_surface(lane.lane_type, road.get_rank()),
self.polygon.clone(),
);
}
let general_road_marking = app.cs().general_road_marking(road.get_rank());
match lane.lane_type {
LaneType::Sidewalk => {
if let Some(c) = app.cs().sidewalk_lines {
batch.extend(c, calculate_sidewalk_lines(lane));
} else {
let width = Distance::meters(0.2);
let shift = (lane.width - width) / 2.0;
batch.push(
general_road_marking,
lane.lane_center_pts
.must_shift_right(shift)
.make_polygons(width),
);
batch.push(
general_road_marking,
lane.lane_center_pts
.must_shift_left(shift)
.make_polygons(width),
);
}
}
LaneType::Shoulder => {}
LaneType::Parking => {
batch.extend(general_road_marking, calculate_parking_lines(lane, map));
}
LaneType::Driving | LaneType::Bus => {
batch.extend(general_road_marking, calculate_driving_lines(lane, road));
batch.extend(general_road_marking, calculate_turn_markings(map, lane));
batch.extend(general_road_marking, calculate_one_way_markings(lane, road));
}
LaneType::Biking => {}
LaneType::SharedLeftTurn => {
let thickness = Distance::meters(0.25);
batch.push(
app.cs().road_center_line(road.get_rank()),
lane.lane_center_pts
.must_shift_right((lane.width - thickness) / 2.0)
.make_polygons(thickness),
);
batch.push(
app.cs().road_center_line(road.get_rank()),
lane.lane_center_pts
.must_shift_left((lane.width - thickness) / 2.0)
.make_polygons(thickness),
);
}
LaneType::Construction => {}
LaneType::LightRail => {
let track_width = lane.width / 4.0;
batch.push(
app.cs().light_rail_track,
lane.lane_center_pts
.must_shift_right((lane.width - track_width) / 2.5)
.make_polygons(track_width),
);
batch.push(
app.cs().light_rail_track,
lane.lane_center_pts
.must_shift_left((lane.width - track_width) / 2.5)
.make_polygons(track_width),
);
let tile_every = Distance::meters(3.0);
let mut dist_along = tile_every;
while dist_along < lane.lane_center_pts.length() - tile_every {
let (pt, angle) = lane.lane_center_pts.must_dist_along(dist_along);
let pt2 = pt.project_away(Distance::meters(1.0), angle);
batch.push(
app.cs().light_rail_track,
perp_line(Line::must_new(pt, pt2), lane.width).make_polygons(track_width),
);
dist_along += tile_every;
}
}
}
if lane.is_bus()
|| lane.is_biking()
|| lane.lane_type == LaneType::Construction
|| lane.lane_type == LaneType::SharedLeftTurn
{
let buffer = Distance::meters(5.0);
let btwn = Distance::meters(30.0);
let len = lane.lane_center_pts.length();
let mut dist = buffer;
while dist + buffer <= len {
let (pt, angle) = lane.lane_center_pts.must_dist_along(dist);
if lane.is_bus() {
batch.append(
GeomBatch::load_svg(prerender, "system/assets/map/bus_only.svg")
.scale(0.06)
.centered_on(pt)
.rotate(angle.shortest_rotation_towards(Angle::degrees(-90.0))),
);
} else if lane.is_biking() {
batch.append(
GeomBatch::load_svg(prerender, "system/assets/meters/bike.svg")
.scale(0.06)
.centered_on(pt)
.rotate(angle.shortest_rotation_towards(Angle::degrees(-90.0))),
);
} else if lane.lane_type == LaneType::SharedLeftTurn {
batch.append(
GeomBatch::load_svg(prerender, "system/assets/map/shared_left_turn.svg")
.autocrop()
.scale(0.003)
.centered_on(pt)
.rotate(angle.shortest_rotation_towards(Angle::degrees(-90.0))),
);
} else if lane.lane_type == LaneType::Construction {
batch.append(
GeomBatch::load_svg(prerender, "system/assets/map/under_construction.svg")
.scale(0.05)
.rotate_around_batch_center(
angle.shortest_rotation_towards(Angle::degrees(-90.0)),
)
.autocrop()
.centered_on(pt),
);
}
dist += btwn;
}
}
if road.is_private() {
batch.push(app.cs().private_road.alpha(0.5), self.polygon.clone());
}
if self.zorder < 0 {
batch = batch.color(RewriteColor::ChangeAlpha(0.5));
}
batch
}
}
impl Renderable for DrawLane {
fn get_id(&self) -> ID {
ID::Lane(self.id)
}
fn draw(&self, g: &mut GfxCtx, app: &dyn AppLike, _: &DrawOptions) {
let mut draw = self.draw_default.borrow_mut();
if draw.is_none() {
*draw = Some(g.upload(self.render(g, app)));
}
g.redraw(draw.as_ref().unwrap());
}
fn get_outline(&self, map: &Map) -> Polygon {
let lane = map.get_l(self.id);
lane.lane_center_pts
.to_thick_boundary(lane.width, OUTLINE_THICKNESS)
.unwrap_or_else(|| self.polygon.clone())
}
fn contains_pt(&self, pt: Pt2D, _: &Map) -> bool {
self.polygon.contains_pt(pt)
}
fn get_zorder(&self) -> isize {
self.zorder
}
}
fn perp_line(l: Line, length: Distance) -> Line {
let pt1 = l.shift_right(length / 2.0).pt1();
let pt2 = l.shift_left(length / 2.0).pt1();
Line::must_new(pt1, pt2)
}
fn calculate_sidewalk_lines(lane: &Lane) -> Vec<Polygon> {
let tile_every = lane.width;
let length = lane.length();
let mut result = Vec::new();
let mut dist_along = tile_every;
while dist_along < length - tile_every {
let (pt, angle) = lane.lane_center_pts.must_dist_along(dist_along);
let pt2 = pt.project_away(Distance::meters(1.0), angle);
result.push(
perp_line(Line::must_new(pt, pt2), lane.width).make_polygons(Distance::meters(0.25)),
);
dist_along += tile_every;
}
result
}
fn calculate_parking_lines(lane: &Lane, map: &Map) -> Vec<Polygon> {
let leg_length = Distance::meters(1.0);
let mut result = Vec::new();
let num_spots = lane.number_parking_spots(map.get_config());
if num_spots > 0 {
for idx in 0..=num_spots {
let (pt, lane_angle) = lane
.lane_center_pts
.must_dist_along(map.get_config().street_parking_spot_length * (1.0 + idx as f64));
let perp_angle = if map.get_config().driving_side == DrivingSide::Right {
lane_angle.rotate_degs(270.0)
} else {
lane_angle.rotate_degs(90.0)
};
let t_pt = pt.project_away(lane.width * 0.4, perp_angle);
let p1 = t_pt.project_away(leg_length, perp_angle.opposite());
result.push(Line::must_new(t_pt, p1).make_polygons(Distance::meters(0.25)));
let p2 = t_pt.project_away(leg_length, lane_angle);
result.push(Line::must_new(t_pt, p2).make_polygons(Distance::meters(0.25)));
let p3 = t_pt.project_away(leg_length, lane_angle.opposite());
result.push(Line::must_new(t_pt, p3).make_polygons(Distance::meters(0.25)));
}
}
result
}
fn calculate_driving_lines(lane: &Lane, parent: &Road) -> Vec<Polygon> {
let lanes = parent.lanes_ltr();
let idx = parent.offset(lane.id);
if idx == 0 || lanes[idx].1 != lanes[idx - 1].1 || lanes[idx].2 != lanes[idx - 1].2 {
return Vec::new();
}
let lane_edge_pts = if lanes[idx].1 == Direction::Fwd {
lane.lane_center_pts.must_shift_left(lane.width / 2.0)
} else {
lane.lane_center_pts.must_shift_right(lane.width / 2.0)
};
lane_edge_pts.dashed_lines(
Distance::meters(0.25),
Distance::meters(1.0),
Distance::meters(1.5),
)
}
fn calculate_turn_markings(map: &Map, lane: &Lane) -> Vec<Polygon> {
if lane.length() < Distance::meters(7.0) {
return Vec::new();
}
let i = map.get_i(lane.dst_i);
if i.outgoing_lanes.iter().all(|l| {
let l = map.get_l(*l);
l.lane_type != lane.lane_type
|| l.parent == lane.parent
|| map
.maybe_get_t(TurnID {
parent: i.id,
src: lane.id,
dst: l.id,
})
.is_some()
}) {
return Vec::new();
}
let mut angles_per_road: HashMap<RoadID, Vec<Angle>> = HashMap::new();
for turn in map.get_turns_from_lane(lane.id) {
angles_per_road
.entry(map.get_l(turn.id.dst).parent)
.or_insert_with(Vec::new)
.push(turn.angle());
}
let mut results = Vec::new();
let thickness = Distance::meters(0.2);
let common_base = lane.lane_center_pts.exact_slice(
lane.length() - Distance::meters(7.0),
lane.length() - Distance::meters(5.0),
);
results.push(common_base.make_polygons(thickness));
for (_, angles) in angles_per_road.into_iter() {
let avg = Angle::average(angles);
results.push(
PolyLine::must_new(vec![
common_base.last_pt(),
common_base.last_pt().project_away(lane.width / 2.0, avg),
])
.make_arrow(thickness, ArrowCap::Triangle),
);
}
results
}
fn calculate_one_way_markings(lane: &Lane, parent: &Road) -> Vec<Polygon> {
let mut results = Vec::new();
let lanes = parent.lanes_ltr();
if lanes
.into_iter()
.any(|(_, d, lt)| lane.dir != d && lt == LaneType::Driving)
{
return results;
}
let arrow_len = Distance::meters(4.0);
let btwn = Distance::meters(30.0);
let thickness = Distance::meters(0.25);
let len = lane.length() - Distance::meters(8.0);
let mut dist = arrow_len;
while dist + arrow_len <= len {
let (pt, angle) = lane.lane_center_pts.must_dist_along(dist);
results.push(
PolyLine::must_new(vec![
pt.project_away(arrow_len / 2.0, angle.opposite()),
pt.project_away(arrow_len / 2.0, angle),
])
.make_arrow(thickness, ArrowCap::Triangle),
);
dist += btwn;
}
results
}