use crate::{ ArenaBox, AvailableSpace, BorrowWindow, Bounds, ElementId, LayoutId, Pixels, Point, Size, ViewContext, WindowContext, ELEMENT_ARENA, }; use derive_more::{Deref, DerefMut}; pub(crate) use smallvec::SmallVec; use std::{any::Any, fmt::Debug}; /// Implemented by types that participate in laying out and painting the contents of a window. /// Elements form a tree and are laid out according to web-based layout rules. /// Rather than calling methods on implementers of this trait directly, you'll usually call `into_any` to convert them into an AnyElement, which manages state internally. /// You can create custom elements by implementing this trait. pub trait Element: 'static + IntoElement { type State: 'static; fn request_layout( &mut self, state: Option, cx: &mut WindowContext, ) -> (LayoutId, Self::State); fn paint(&mut self, bounds: Bounds, state: &mut Self::State, cx: &mut WindowContext); fn into_any(self) -> AnyElement { AnyElement::new(self) } } /// Implemented by any type that can be converted into an element. pub trait IntoElement: Sized { /// The specific type of element into which the implementing type is converted. type Element: Element; /// The [`ElementId`] of self once converted into an [`Element`]. /// If present, the resulting element's state will be carried across frames. fn element_id(&self) -> Option; /// Convert self into a type that implements [`Element`]. fn into_element(self) -> Self::Element; /// Convert self into a dynamically-typed [`AnyElement`]. fn into_any_element(self) -> AnyElement { self.into_element().into_any() } /// Convert into an element, then draw in the current window at the given origin. /// The available space argument is provided to the layout engine to determine the size of the // root element. Once the element is drawn, its associated element state is yielded to the // given callback. fn draw_and_update_state( self, origin: Point, available_space: Size, cx: &mut WindowContext, f: impl FnOnce(&mut ::State, &mut WindowContext) -> R, ) -> R where T: Clone + Default + Debug + Into, { let element = self.into_element(); let element_id = element.element_id(); let element = DrawableElement { element: Some(element), phase: ElementDrawPhase::Start, }; let frame_state = DrawableElement::draw(element, origin, available_space.map(Into::into), cx); if let Some(mut frame_state) = frame_state { f(&mut frame_state, cx) } else { cx.with_element_state(element_id.unwrap(), |element_state, cx| { let mut element_state = element_state.unwrap(); let result = f(&mut element_state, cx); (result, element_state) }) } } /// Convert self to another type by calling the given closure. Useful in rendering code. fn map(self, f: impl FnOnce(Self) -> U) -> U where Self: Sized, U: IntoElement, { f(self) } /// Conditionally chain onto self with the given closure. Useful in rendering code. fn when(self, condition: bool, then: impl FnOnce(Self) -> Self) -> Self where Self: Sized, { self.map(|this| if condition { then(this) } else { this }) } /// Conditionally chain onto self with the given closure if the given option is Some. /// The contents of the option are provided to the closure. fn when_some(self, option: Option, then: impl FnOnce(Self, T) -> Self) -> Self where Self: Sized, { self.map(|this| { if let Some(value) = option { then(this, value) } else { this } }) } } pub trait Render: 'static + Sized { fn render(&mut self, cx: &mut ViewContext) -> impl IntoElement; } impl Render for () { fn render(&mut self, _cx: &mut ViewContext) -> impl IntoElement { () } } /// You can derive [`IntoElement`] on any type that implements this trait. /// It is used to allow views to be expressed in terms of abstract data. pub trait RenderOnce: 'static { fn render(self, cx: &mut WindowContext) -> impl IntoElement; } pub trait ParentElement { fn children_mut(&mut self) -> &mut SmallVec<[AnyElement; 2]>; fn child(mut self, child: impl IntoElement) -> Self where Self: Sized, { self.children_mut().push(child.into_element().into_any()); self } fn children(mut self, children: impl IntoIterator) -> Self where Self: Sized, { self.children_mut() .extend(children.into_iter().map(|child| child.into_any_element())); self } } pub struct Component(Option); impl Component { pub fn new(component: C) -> Self { Component(Some(component)) } } impl Element for Component { type State = AnyElement; fn request_layout( &mut self, _: Option, cx: &mut WindowContext, ) -> (LayoutId, Self::State) { let mut element = self.0.take().unwrap().render(cx).into_any_element(); let layout_id = element.request_layout(cx); (layout_id, element) } fn paint(&mut self, _: Bounds, element: &mut Self::State, cx: &mut WindowContext) { element.paint(cx) } } impl IntoElement for Component { type Element = Self; fn element_id(&self) -> Option { None } fn into_element(self) -> Self::Element { self } } #[derive(Deref, DerefMut, Default, Clone, Debug, Eq, PartialEq, Hash)] pub struct GlobalElementId(SmallVec<[ElementId; 32]>); trait ElementObject { fn element_id(&self) -> Option; fn request_layout(&mut self, cx: &mut WindowContext) -> LayoutId; fn paint(&mut self, cx: &mut WindowContext); fn measure( &mut self, available_space: Size, cx: &mut WindowContext, ) -> Size; fn draw( &mut self, origin: Point, available_space: Size, cx: &mut WindowContext, ); } pub struct DrawableElement { element: Option, phase: ElementDrawPhase, } #[derive(Default)] enum ElementDrawPhase { #[default] Start, LayoutRequested { layout_id: LayoutId, frame_state: Option, }, LayoutComputed { layout_id: LayoutId, available_space: Size, frame_state: Option, }, } /// A wrapper around an implementer of [`Element`] that allows it to be drawn in a window. impl DrawableElement { fn new(element: E) -> Self { DrawableElement { element: Some(element), phase: ElementDrawPhase::Start, } } fn element_id(&self) -> Option { self.element.as_ref()?.element_id() } fn request_layout(&mut self, cx: &mut WindowContext) -> LayoutId { let (layout_id, frame_state) = if let Some(id) = self.element.as_ref().unwrap().element_id() { let layout_id = cx.with_element_state(id, |element_state, cx| { self.element .as_mut() .unwrap() .request_layout(element_state, cx) }); (layout_id, None) } else { let (layout_id, frame_state) = self.element.as_mut().unwrap().request_layout(None, cx); (layout_id, Some(frame_state)) }; self.phase = ElementDrawPhase::LayoutRequested { layout_id, frame_state, }; layout_id } fn paint(mut self, cx: &mut WindowContext) -> Option { match self.phase { ElementDrawPhase::LayoutRequested { layout_id, frame_state, } | ElementDrawPhase::LayoutComputed { layout_id, frame_state, .. } => { let bounds = cx.layout_bounds(layout_id); if let Some(mut frame_state) = frame_state { self.element .take() .unwrap() .paint(bounds, &mut frame_state, cx); Some(frame_state) } else { let element_id = self .element .as_ref() .unwrap() .element_id() .expect("if we don't have frame state, we should have element state"); cx.with_element_state(element_id, |element_state, cx| { let mut element_state = element_state.unwrap(); self.element .take() .unwrap() .paint(bounds, &mut element_state, cx); ((), element_state) }); None } } _ => panic!("must call layout before paint"), } } fn measure( &mut self, available_space: Size, cx: &mut WindowContext, ) -> Size { if matches!(&self.phase, ElementDrawPhase::Start) { self.request_layout(cx); } let layout_id = match &mut self.phase { ElementDrawPhase::LayoutRequested { layout_id, frame_state, } => { cx.compute_layout(*layout_id, available_space); let layout_id = *layout_id; self.phase = ElementDrawPhase::LayoutComputed { layout_id, available_space, frame_state: frame_state.take(), }; layout_id } ElementDrawPhase::LayoutComputed { layout_id, available_space: prev_available_space, .. } => { if available_space != *prev_available_space { cx.compute_layout(*layout_id, available_space); *prev_available_space = available_space; } *layout_id } _ => panic!("cannot measure after painting"), }; cx.layout_bounds(layout_id).size } fn draw( mut self, origin: Point, available_space: Size, cx: &mut WindowContext, ) -> Option { self.measure(available_space, cx); cx.with_absolute_element_offset(origin, |cx| self.paint(cx)) } } impl ElementObject for Option> where E: Element, E::State: 'static, { fn element_id(&self) -> Option { self.as_ref().unwrap().element_id() } fn request_layout(&mut self, cx: &mut WindowContext) -> LayoutId { DrawableElement::request_layout(self.as_mut().unwrap(), cx) } fn paint(&mut self, cx: &mut WindowContext) { DrawableElement::paint(self.take().unwrap(), cx); } fn measure( &mut self, available_space: Size, cx: &mut WindowContext, ) -> Size { DrawableElement::measure(self.as_mut().unwrap(), available_space, cx) } fn draw( &mut self, origin: Point, available_space: Size, cx: &mut WindowContext, ) { DrawableElement::draw(self.take().unwrap(), origin, available_space, cx); } } pub struct AnyElement(ArenaBox); impl AnyElement { pub fn new(element: E) -> Self where E: 'static + Element, E::State: Any, { let element = ELEMENT_ARENA .with_borrow_mut(|arena| arena.alloc(|| Some(DrawableElement::new(element)))) .map(|element| element as &mut dyn ElementObject); AnyElement(element) } pub fn request_layout(&mut self, cx: &mut WindowContext) -> LayoutId { self.0.request_layout(cx) } pub fn paint(&mut self, cx: &mut WindowContext) { self.0.paint(cx) } /// Initializes this element and performs layout within the given available space to determine its size. pub fn measure( &mut self, available_space: Size, cx: &mut WindowContext, ) -> Size { self.0.measure(available_space, cx) } /// Initializes this element and performs layout in the available space, then paints it at the given origin. pub fn draw( &mut self, origin: Point, available_space: Size, cx: &mut WindowContext, ) { self.0.draw(origin, available_space, cx) } pub fn inner_id(&self) -> Option { self.0.element_id() } } impl Element for AnyElement { type State = (); fn request_layout( &mut self, _: Option, cx: &mut WindowContext, ) -> (LayoutId, Self::State) { let layout_id = self.request_layout(cx); (layout_id, ()) } fn paint(&mut self, _: Bounds, _: &mut Self::State, cx: &mut WindowContext) { self.paint(cx) } } impl IntoElement for AnyElement { type Element = Self; fn element_id(&self) -> Option { None } fn into_element(self) -> Self::Element { self } fn into_any_element(self) -> AnyElement { self } } /// The empty element, which renders nothing. pub type Empty = (); impl IntoElement for () { type Element = Self; fn element_id(&self) -> Option { None } fn into_element(self) -> Self::Element { self } } impl Element for () { type State = (); fn request_layout( &mut self, _state: Option, cx: &mut WindowContext, ) -> (LayoutId, Self::State) { (cx.request_layout(&crate::Style::default(), None), ()) } fn paint( &mut self, _bounds: Bounds, _state: &mut Self::State, _cx: &mut WindowContext, ) { } }