use abstio::MapName;
use abstutil::{CmdArgs, Timer};
use geom::{Circle, Distance, Duration, Pt2D, Time};
use map_model::{IntersectionID, Map};
use sim::Sim;
use widgetry::{Canvas, EventCtx, GfxCtx, SharedAppState, State, Transition, Warper};
use crate::colors::ColorScheme;
use crate::load::MapLoader;
use crate::options::Options;
use crate::render::DrawMap;
use crate::render::{DrawOptions, Renderable};
use crate::tools::{CameraState, URLManager};
use crate::{AppLike, ID};
pub struct SimpleApp<T> {
pub map: Map,
pub draw_map: DrawMap,
pub cs: ColorScheme,
pub opts: Options,
pub current_selection: Option<ID>,
pub session: T,
pub time: Time,
}
impl<T: 'static> SimpleApp<T> {
pub fn new<
F: 'static + Fn(&mut EventCtx, &mut SimpleApp<T>) -> Vec<Box<dyn State<SimpleApp<T>>>>,
>(
ctx: &mut EventCtx,
mut opts: Options,
session: T,
init_states: F,
) -> (SimpleApp<T>, Vec<Box<dyn State<SimpleApp<T>>>>) {
let mut args = CmdArgs::new();
opts.update_from_args(&mut args);
let map_name = args
.optional_free()
.map(|path| MapName::from_path(&path).expect(&format!("bad map path: {}", path)))
.or_else(|| {
abstio::maybe_read_json::<crate::tools::DefaultMap>(
abstio::path_player("maps.json"),
&mut Timer::throwaway(),
)
.ok()
.map(|x| x.last_map)
})
.unwrap_or(MapName::seattle("montlake"));
let center_camera = args.optional("--cam");
args.done();
let cs = ColorScheme::new(ctx, opts.color_scheme);
let map = Map::blank();
let draw_map = DrawMap::new(ctx, &map, &opts, &cs, &mut Timer::throwaway());
let app = SimpleApp {
map,
draw_map,
cs,
opts,
current_selection: None,
session,
time: Time::START_OF_DAY,
};
let states = vec![MapLoader::new(
ctx,
&app,
map_name,
Box::new(move |ctx, app| {
if let Some((pt, zoom)) =
center_camera.and_then(|cam| URLManager::parse_center_camera(app, cam))
{
ctx.canvas.cam_zoom = zoom;
ctx.canvas.center_on_map_pt(pt);
}
Transition::Clear(init_states(ctx, app))
}),
)];
(app, states)
}
pub fn draw_unzoomed(&self, g: &mut GfxCtx) {
g.clear(self.cs.void_background);
g.redraw(&self.draw_map.boundary_polygon);
g.redraw(&self.draw_map.draw_all_areas);
g.redraw(&self.draw_map.draw_all_unzoomed_parking_lots);
g.redraw(&self.draw_map.draw_all_unzoomed_roads_and_intersections);
g.redraw(&self.draw_map.draw_all_buildings);
if let Some(ID::Area(id)) = self.current_selection {
g.draw_polygon(
self.cs.selected,
self.draw_map.get_a(id).get_outline(&self.map),
);
} else if let Some(ID::Road(id)) = self.current_selection {
g.draw_polygon(
self.cs.selected,
self.draw_map.get_r(id).get_outline(&self.map),
);
} else if let Some(ID::Intersection(id)) = self.current_selection {
g.draw_polygon(self.cs.selected, self.map.get_i(id).polygon.clone());
} else if let Some(ID::Building(id)) = self.current_selection {
g.draw_polygon(self.cs.selected, self.map.get_b(id).polygon.clone());
}
}
pub fn draw_zoomed(&self, g: &mut GfxCtx, opts: DrawOptions) {
g.clear(self.cs.void_background);
g.redraw(&self.draw_map.boundary_polygon);
let objects = self
.draw_map
.get_renderables_back_to_front(g.get_screen_bounds(), &self.map);
let mut drawn_all_buildings = false;
let mut drawn_all_areas = false;
for obj in objects {
obj.draw(g, self, &opts);
match obj.get_id() {
ID::Building(_) => {
if !drawn_all_buildings {
if opts.show_building_driveways {
g.redraw(&self.draw_map.draw_all_building_driveways);
}
g.redraw(&self.draw_map.draw_all_buildings);
g.redraw(&self.draw_map.draw_all_building_outlines);
drawn_all_buildings = true;
}
}
ID::Area(_) => {
if !drawn_all_areas {
g.redraw(&self.draw_map.draw_all_areas);
drawn_all_areas = true;
}
}
_ => {}
}
if self.current_selection == Some(obj.get_id()) {
g.draw_polygon(self.cs.selected, obj.get_outline(&self.map));
}
}
}
pub fn recalculate_current_selection(&mut self, ctx: &EventCtx) {
self.current_selection = self.calculate_current_selection(ctx, false, false);
}
pub fn mouseover_unzoomed_roads_and_intersections(&self, ctx: &EventCtx) -> Option<ID> {
self.calculate_current_selection(ctx, true, false)
}
pub fn mouseover_unzoomed_buildings(&self, ctx: &EventCtx) -> Option<ID> {
self.calculate_current_selection(ctx, false, true)
.filter(|id| match id {
ID::Building(_) => true,
_ => false,
})
}
fn calculate_current_selection(
&self,
ctx: &EventCtx,
unzoomed_roads_and_intersections: bool,
unzoomed_buildings: bool,
) -> Option<ID> {
if ctx.canvas.cam_zoom < self.opts.min_zoom_for_detail
&& !(unzoomed_roads_and_intersections || unzoomed_buildings)
{
return None;
}
let pt = ctx.canvas.get_cursor_in_map_space()?;
let mut objects = self.draw_map.get_renderables_back_to_front(
Circle::new(pt, Distance::meters(3.0)).get_bounds(),
&self.map,
);
objects.reverse();
for obj in objects {
match obj.get_id() {
ID::Road(_) => {
if !unzoomed_roads_and_intersections
|| ctx.canvas.cam_zoom >= self.opts.min_zoom_for_detail
{
continue;
}
}
ID::Intersection(_) => {
if ctx.canvas.cam_zoom < self.opts.min_zoom_for_detail
&& !unzoomed_roads_and_intersections
{
continue;
}
}
ID::Building(_) => {
if ctx.canvas.cam_zoom < self.opts.min_zoom_for_detail && !unzoomed_buildings {
continue;
}
}
_ => {
if ctx.canvas.cam_zoom < self.opts.min_zoom_for_detail {
continue;
}
}
}
if obj.contains_pt(pt, &self.map) {
return Some(obj.get_id());
}
}
None
}
}
impl<T: 'static> AppLike for SimpleApp<T> {
#[inline]
fn map(&self) -> &Map {
&self.map
}
#[inline]
fn sim(&self) -> &Sim {
unreachable!()
}
#[inline]
fn cs(&self) -> &ColorScheme {
&self.cs
}
#[inline]
fn mut_cs(&mut self) -> &mut ColorScheme {
&mut self.cs
}
#[inline]
fn draw_map(&self) -> &DrawMap {
&self.draw_map
}
#[inline]
fn mut_draw_map(&mut self) -> &mut DrawMap {
&mut self.draw_map
}
#[inline]
fn opts(&self) -> &Options {
&self.opts
}
#[inline]
fn mut_opts(&mut self) -> &mut Options {
&mut self.opts
}
fn map_switched(&mut self, ctx: &mut EventCtx, map: Map, timer: &mut Timer) {
CameraState::save(ctx.canvas, self.map.get_name());
self.map = map;
self.draw_map = DrawMap::new(ctx, &self.map, &self.opts, &self.cs, timer);
CameraState::load(ctx, self.map.get_name());
}
fn draw_with_opts(&self, g: &mut GfxCtx, opts: DrawOptions) {
if g.canvas.cam_zoom < self.opts.min_zoom_for_detail {
self.draw_unzoomed(g);
} else {
self.draw_zoomed(g, opts);
}
}
fn make_warper(
&mut self,
ctx: &EventCtx,
pt: Pt2D,
target_cam_zoom: Option<f64>,
_: Option<ID>,
) -> Box<dyn State<SimpleApp<T>>> {
Box::new(SimpleWarper {
warper: Warper::new(ctx, pt, target_cam_zoom),
})
}
fn sim_time(&self) -> Time {
self.time
}
fn current_stage_and_remaining_time(&self, id: IntersectionID) -> (usize, Duration) {
let signal = self.map.get_traffic_signal(id);
let mut time_left = (self.time - Time::START_OF_DAY) % signal.simple_cycle_duration();
for (idx, stage) in signal.stages.iter().enumerate() {
if time_left < stage.stage_type.simple_duration() {
return (idx, time_left);
}
time_left -= stage.stage_type.simple_duration();
}
unreachable!()
}
}
impl<T: 'static> SharedAppState for SimpleApp<T> {
fn draw_default(&self, g: &mut GfxCtx) {
self.draw_with_opts(g, DrawOptions::new());
}
fn dump_before_abort(&self, canvas: &Canvas) {
CameraState::save(canvas, self.map.get_name());
}
fn before_quit(&self, canvas: &Canvas) {
CameraState::save(canvas, self.map.get_name());
}
}
struct SimpleWarper {
warper: Warper,
}
impl<T> State<SimpleApp<T>> for SimpleWarper {
fn event(&mut self, ctx: &mut EventCtx, _: &mut SimpleApp<T>) -> Transition<SimpleApp<T>> {
if self.warper.event(ctx) {
Transition::Keep
} else {
Transition::Pop
}
}
fn draw(&self, _: &mut GfxCtx, _: &SimpleApp<T>) {}
}