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path: root/helix-term/src/compositor.rs
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// Each component declares it's own size constraints and gets fitted based on it's parent.
// Q: how does this work with popups?
// cursive does compositor.screen_mut().add_layer_at(pos::absolute(x, y), <component>)

use crossterm::event::Event;
use helix_core::Position;
use tui::{buffer::Buffer as Surface, layout::Rect};

pub type Callback = Box<dyn FnOnce(&mut Compositor)>;

// --> EventResult should have a callback that takes a context with methods like .popup(),
// .prompt() etc. That way we can abstract it from the renderer.
// Q: How does this interact with popups where we need to be able to specify the rendering of the
// popup?
// A: It could just take a textarea.
//
// If Compositor was specified in the callback that's then problematic because of

// Cursive-inspired
pub enum EventResult {
    Ignored,
    Consumed(Option<Callback>),
}

use helix_view::Editor;

use crate::application::LspCallbacks;

pub struct Context<'a> {
    pub editor: &'a mut Editor,
    pub scroll: Option<usize>,
    pub callbacks: &'a mut LspCallbacks,
}

pub trait Component: Any + AnyComponent {
    /// Process input events, return true if handled.
    fn handle_event(&mut self, event: Event, ctx: &mut Context) -> EventResult {
        EventResult::Ignored
    }
    // , args: ()

    /// Should redraw? Useful for saving redraw cycles if we know component didn't change.
    fn should_update(&self) -> bool {
        true
    }

    /// Render the component onto the provided surface.
    fn render(&self, area: Rect, frame: &mut Surface, ctx: &mut Context);

    fn cursor_position(&self, area: Rect, ctx: &Editor) -> Option<Position> {
        None
    }

    /// May be used by the parent component to compute the child area.
    /// viewport is the maximum allowed area, and the child should stay within those bounds.
    fn required_size(&mut self, viewport: (u16, u16)) -> Option<(u16, u16)> {
        // TODO: for scrolling, the scroll wrapper should place a size + offset on the Context
        // that way render can use it
        None
    }

    fn type_name(&self) -> &'static str {
        std::any::type_name::<Self>()
    }
}

use anyhow::Error;
use std::io::stdout;
use tui::backend::CrosstermBackend;
type Terminal = tui::terminal::Terminal<CrosstermBackend<std::io::Stdout>>;

pub struct Compositor {
    layers: Vec<Box<dyn Component>>,
    terminal: Terminal,
}

impl Compositor {
    pub fn new() -> Result<Self, Error> {
        let backend = CrosstermBackend::new(stdout());
        let mut terminal = Terminal::new(backend)?;
        Ok(Self {
            layers: Vec::new(),
            terminal,
        })
    }

    pub fn size(&self) -> Rect {
        self.terminal.size().expect("couldn't get terminal size")
    }

    pub fn resize(&mut self, width: u16, height: u16) {
        self.terminal
            .resize(Rect::new(0, 0, width, height))
            .expect("Unable to resize terminal")
    }

    pub fn push(&mut self, mut layer: Box<dyn Component>) {
        let size = self.size();
        // trigger required_size on init
        layer.required_size((size.width, size.height));
        self.layers.push(layer);
    }

    pub fn pop(&mut self) {
        self.layers.pop();
    }

    pub fn handle_event(&mut self, event: Event, cx: &mut Context) -> bool {
        // propagate events through the layers until we either find a layer that consumes it or we
        // run out of layers (event bubbling)
        for layer in self.layers.iter_mut().rev() {
            match layer.handle_event(event, cx) {
                EventResult::Consumed(Some(callback)) => {
                    callback(self);
                    return true;
                }
                EventResult::Consumed(None) => return true,
                EventResult::Ignored => false,
            };
        }
        false
    }

    pub fn render(&mut self, cx: &mut Context) {
        self.terminal.autoresize().unwrap();
        let area = self.size();

        let surface = self.terminal.current_buffer_mut();

        for layer in &self.layers {
            layer.render(area, surface, cx)
        }

        let pos = self
            .cursor_position(area, cx.editor)
            .map(|pos| (pos.col as u16, pos.row as u16));

        self.terminal.draw(pos);
    }

    pub fn cursor_position(&self, area: Rect, editor: &Editor) -> Option<Position> {
        for layer in self.layers.iter().rev() {
            if let Some(pos) = layer.cursor_position(area, editor) {
                return Some(pos);
            }
        }
        None
    }

    pub fn find(&mut self, type_name: &str) -> Option<&mut dyn Component> {
        self.layers
            .iter_mut()
            .find(|component| component.type_name() == type_name)
            .map(|component| component.as_mut())
    }
}

// View casting, taken straight from Cursive

use std::any::Any;

/// A view that can be downcasted to its concrete type.
///
/// This trait is automatically implemented for any `T: Component`.
pub trait AnyComponent {
    /// Downcast self to a `Any`.
    fn as_any(&self) -> &dyn Any;

    /// Downcast self to a mutable `Any`.
    fn as_any_mut(&mut self) -> &mut dyn Any;

    /// Returns a boxed any from a boxed self.
    ///
    /// Can be used before `Box::downcast()`.
    ///
    /// # Examples
    ///
    /// ```rust
    /// # use cursive_core::views::TextComponent;
    /// # use cursive_core::view::Component;
    /// let boxed: Box<Component> = Box::new(TextComponent::new("text"));
    /// let text: Box<TextComponent> = boxed.as_boxed_any().downcast().unwrap();
    /// ```
    fn as_boxed_any(self: Box<Self>) -> Box<dyn Any>;
}

impl<T: Component> AnyComponent for T {
    /// Downcast self to a `Any`.
    fn as_any(&self) -> &dyn Any {
        self
    }

    /// Downcast self to a mutable `Any`.
    fn as_any_mut(&mut self) -> &mut dyn Any {
        self
    }

    fn as_boxed_any(self: Box<Self>) -> Box<dyn Any> {
        self
    }
}

impl dyn AnyComponent {
    /// Attempts to downcast `self` to a concrete type.
    pub fn downcast_ref<T: Any>(&self) -> Option<&T> {
        self.as_any().downcast_ref()
    }

    /// Attempts to downcast `self` to a concrete type.
    pub fn downcast_mut<T: Any>(&mut self) -> Option<&mut T> {
        self.as_any_mut().downcast_mut()
    }

    /// Attempts to downcast `Box<Self>` to a concrete type.
    pub fn downcast<T: Any>(self: Box<Self>) -> Result<Box<T>, Box<Self>> {
        // Do the check here + unwrap, so the error
        // value is `Self` and not `dyn Any`.
        if self.as_any().is::<T>() {
            Ok(self.as_boxed_any().downcast().unwrap())
        } else {
            Err(self)
        }
    }

    /// Checks if this view is of type `T`.
    pub fn is<T: Any>(&mut self) -> bool {
        self.as_any().is::<T>()
    }
}