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//! A widgetry application splits its state into two pieces: global shared state that lasts for the
//! entire lifetime of the application, and a stack of smaller states, only one of which is active
//! at a time. For example, imagine an application to view a map. The shared state would include
//! the map and pre-rendered geometry for it. The individual states might start with a splash
//! screen or menu to choose a map, then a map viewer, then maybe a state to drill down into pieces
//! of the map.
use abstutil::CloneableAny;
use crate::{Canvas, Color, EventCtx, GfxCtx, Outcome, Panel};
/// Any data that should last the entire lifetime of the application should be stored in the struct
/// implementing this trait.
pub trait SharedAppState {
/// Before `State::event` is called, call this.
fn before_event(&mut self) {}
/// When DrawBaselayer::DefaultDraw is called, run this.
fn draw_default(&self, _: &mut GfxCtx) {}
/// Will be called if `State::event` or `State::draw` panics.
fn dump_before_abort(&self, _: &Canvas) {}
/// Called before a normal exit, like window close
fn before_quit(&self, _: &Canvas) {}
/// If widgetry determines the video card is low on memory, this may be called. The application
/// should make its best effort to delete any unused Drawables.
fn free_memory(&mut self) {}
}
pub(crate) struct App<A: SharedAppState> {
/// A stack of states
pub(crate) states: Vec<Box<dyn State<A>>>,
pub(crate) shared_app_state: A,
}
impl<A: SharedAppState> App<A> {
pub(crate) fn event(&mut self, ctx: &mut EventCtx) {
self.shared_app_state.before_event();
let transition = self
.states
.last_mut()
.unwrap()
.event(ctx, &mut self.shared_app_state);
if self.execute_transition(ctx, transition) {
// Let the new state initialize with a fake event. Usually these just return
// Transition::Keep, but nothing stops them from doing whatever. (For example, entering
// tutorial mode immediately pushes on a Warper.) So just recurse.
ctx.no_op_event(true, |ctx| self.event(ctx));
}
}
pub(crate) fn draw(&self, g: &mut GfxCtx) {
let state = self.states.last().unwrap();
match state.draw_baselayer() {
DrawBaselayer::DefaultDraw => {
self.shared_app_state.draw_default(g);
}
DrawBaselayer::Custom => {}
DrawBaselayer::PreviousState => {
if self.states.len() >= 2 {
match self.states[self.states.len() - 2].draw_baselayer() {
DrawBaselayer::DefaultDraw => {
self.shared_app_state.draw_default(g);
}
DrawBaselayer::Custom => {}
// Don't recurse, but at least clear the screen, because the state is
// usually expecting the previous thing to happen.
DrawBaselayer::PreviousState => {
g.clear(Color::BLACK);
}
}
self.states[self.states.len() - 2].draw(g, &self.shared_app_state);
} else {
// I'm not entirely sure why this happens, but crashing isn't ideal.
warn!(
"A state requested DrawBaselayer::PreviousState, but it's the only state \
on the stack!"
);
g.clear(Color::BLACK);
}
}
}
state.draw(g, &self.shared_app_state);
}
/// If true, then the top-most state on the stack needs to be "woken up" with a fake mouseover
/// event.
fn execute_transition(&mut self, ctx: &mut EventCtx, transition: Transition<A>) -> bool {
match transition {
Transition::Keep => false,
Transition::KeepWithMouseover => true,
Transition::Pop => {
let mut state = self.states.pop().unwrap();
state.on_destroy(ctx, &mut self.shared_app_state);
if self.states.is_empty() {
if cfg!(target_arch = "wasm32") {
// Just kidding, don't actually leave.
self.states.push(state);
// TODO Once PopupMsg is lifted here, add an explanation
} else {
self.shared_app_state.before_quit(ctx.canvas);
std::process::exit(0);
}
}
true
}
Transition::ModifyState(cb) => {
cb(
self.states.last_mut().unwrap(),
ctx,
&mut self.shared_app_state,
);
true
}
Transition::ConsumeState(cb) => {
let mut last = self.states.pop().unwrap();
last.on_destroy(ctx, &mut self.shared_app_state);
let new_states = cb(last, ctx, &mut self.shared_app_state);
self.states.extend(new_states);
true
}
Transition::Push(state) => {
self.states.push(state);
true
}
Transition::Replace(state) => {
self.states
.pop()
.unwrap()
.on_destroy(ctx, &mut self.shared_app_state);
self.states.push(state);
true
}
Transition::Clear(states) => {
while !self.states.is_empty() {
self.states
.pop()
.unwrap()
.on_destroy(ctx, &mut self.shared_app_state);
}
self.states.extend(states);
true
}
Transition::Multi(list) => {
// Always wake-up just the last state remaining after the sequence
for t in list {
self.execute_transition(ctx, t);
}
true
}
}
}
}
/// Before `State::draw` is called, draw something else.
pub enum DrawBaselayer {
/// Call `SharedAppState::draw_default`.
DefaultDraw,
/// Don't draw anything.
Custom,
/// Call the previous state's `draw`. This won't recurse, even if that state specifies
/// `PreviousState`.
PreviousState,
}
/// A temporary state of an application. There's a stack of these, with the most recent being the
/// active one.
pub trait State<A>: downcast_rs::Downcast {
/// Respond to a UI event, such as input or time passing.
fn event(&mut self, ctx: &mut EventCtx, shared_app_state: &mut A) -> Transition<A>;
/// Draw
fn draw(&self, g: &mut GfxCtx, shared_app_state: &A);
/// Specifies what to draw before draw()
fn draw_baselayer(&self) -> DrawBaselayer {
DrawBaselayer::DefaultDraw
}
/// Before this state is popped or replaced, call this.
fn on_destroy(&mut self, _: &mut EventCtx, _: &mut A) {}
// We don't need an on_enter -- the constructor for the state can just do it.
}
downcast_rs::impl_downcast!(State<A>);
/// When a state responds to an event, it can specify some way to manipulate the stack of states.
pub enum Transition<A> {
/// Don't do anything, keep the current state as the active one
Keep,
/// Keep the current state as the active one, but immediately call `event` again with a mouse
/// moved event
KeepWithMouseover,
/// Destroy the current state, and resume from the previous one
Pop,
/// If a state needs to pass data back to its parent, use this. In the callback, you have to
/// downcast the previous state to populate it with data.
ModifyState(Box<dyn FnOnce(&mut Box<dyn State<A>>, &mut EventCtx, &mut A)>),
/// This destroys the current state, running the callback on it, and pushes new states onto the
/// stack. The callback can consume the current state, thus salvaging fields from it without
/// cloning.
ConsumeState(
Box<dyn FnOnce(Box<dyn State<A>>, &mut EventCtx, &mut A) -> Vec<Box<dyn State<A>>>>,
),
/// Push a new active state on the top of the stack.
Push(Box<dyn State<A>>),
/// Replace the current state with a new one. Equivalent to Pop, then Push.
Replace(Box<dyn State<A>>),
/// Replace the entire stack of states with this stack.
Clear(Vec<Box<dyn State<A>>>),
/// Execute a sequence of transitions in order.
Multi(Vec<Transition<A>>),
}
/// Many states fit a pattern of managing a single panel, handling mouseover events, and other
/// interactions on the map. Implementing this instead of `State` reduces some boilerplate.
pub trait SimpleState<A> {
/// Called when something on the panel has been clicked. Since the action is just a string,
/// the fallback case can just use `unreachable!()`.
fn on_click(
&mut self,
ctx: &mut EventCtx,
app: &mut A,
action: &str,
panel: &mut Panel,
) -> Transition<A>;
/// Called when something on the panel has been clicked.
fn on_click_custom(
&mut self,
_ctx: &mut EventCtx,
_app: &mut A,
_action: Box<dyn CloneableAny>,
_panel: &mut Panel,
) -> Transition<A> {
Transition::Keep
}
/// Called when something on the panel has changed. If a transition is returned, stop handling
/// the event and immediately apply the transition.
fn panel_changed(
&mut self,
_: &mut EventCtx,
_: &mut A,
_: &mut Panel,
) -> Option<Transition<A>> {
None
}
/// Called when the mouse has moved.
fn on_mouseover(&mut self, _: &mut EventCtx, _: &mut A) {}
/// If a panel `on_click` event didn't occur and `panel_changed` didn't return transition, then
/// call this to handle all other events.
fn other_event(&mut self, _: &mut EventCtx, _: &mut A) -> Transition<A> {
Transition::Keep
}
fn draw(&self, _: &mut GfxCtx, _: &A) {}
fn draw_baselayer(&self) -> DrawBaselayer {
DrawBaselayer::DefaultDraw
}
}
impl<A: 'static> dyn SimpleState<A> {
pub fn new_state(panel: Panel, inner: Box<dyn SimpleState<A>>) -> Box<dyn State<A>> {
Box::new(SimpleStateWrapper { panel, inner })
}
}
pub struct SimpleStateWrapper<A> {
panel: Panel,
inner: Box<dyn SimpleState<A>>,
}
impl<A: 'static> State<A> for SimpleStateWrapper<A> {
fn event(&mut self, ctx: &mut EventCtx, app: &mut A) -> Transition<A> {
if ctx.redo_mouseover() {
self.inner.on_mouseover(ctx, app);
}
match self.panel.event(ctx) {
Outcome::Clicked(action) => self.inner.on_click(ctx, app, &action, &mut self.panel),
Outcome::ClickCustom(data) => {
self.inner.on_click_custom(ctx, app, data, &mut self.panel)
}
Outcome::Changed(_) => self
.inner
.panel_changed(ctx, app, &mut self.panel)
.unwrap_or_else(|| self.inner.other_event(ctx, app)),
Outcome::DragDropReleased(_, _, _) | Outcome::Focused(_) | Outcome::Nothing => {
self.inner.other_event(ctx, app)
}
}
}
fn draw(&self, g: &mut GfxCtx, app: &A) {
self.inner.draw(g, app);
// Draw last
self.panel.draw(g);
}
fn draw_baselayer(&self) -> DrawBaselayer {
self.inner.draw_baselayer()
}
}