use std::f64::consts::SQRT_2; use crate::library::prelude::*; use crate::library::text::TextNode; /// Place a node into a sizable and fillable shape. #[derive(Debug, Hash)] pub struct ShapeNode(pub Option); /// Place a node into a square. pub type SquareNode = ShapeNode; /// Place a node into a rectangle. pub type RectNode = ShapeNode; /// Place a node into a circle. pub type CircleNode = ShapeNode; /// Place a node into an ellipse. pub type EllipseNode = ShapeNode; #[node] impl ShapeNode { /// How to fill the shape. pub const FILL: Option = None; /// How to stroke the shape. #[property(resolve, fold)] pub const STROKE: Smart> = Smart::Auto; /// How much to pad the shape's content. pub const PADDING: Relative = Relative::zero(); fn construct(_: &mut Context, args: &mut Args) -> TypResult { let size = match S { SQUARE => args.named::("size")?.map(Relative::from), CIRCLE => args.named::("radius")?.map(|r| 2.0 * Relative::from(r)), _ => None, }; let width = match size { None => args.named("width")?, size => size, }; let height = match size { None => args.named("height")?, size => size, }; Ok(Content::inline( Self(args.find()?).pack().sized(Spec::new(width, height)), )) } } impl Layout for ShapeNode { fn layout( &self, ctx: &mut Context, regions: &Regions, styles: StyleChain, ) -> TypResult>> { let mut frames; if let Some(child) = &self.0 { let mut padding = styles.get(Self::PADDING); if is_round(S) { padding.rel += Ratio::new(0.5 - SQRT_2 / 4.0); } // Pad the child. let child = child.clone().padded(Sides::splat(padding)); let mut pod = Regions::one(regions.first, regions.base, regions.expand); frames = child.layout(ctx, &pod, styles)?; // Relayout with full expansion into square region to make sure // the result is really a square or circle. if is_quadratic(S) { let length = if regions.expand.x || regions.expand.y { let target = regions.expand.select(regions.first, Size::zero()); target.x.max(target.y) } else { let size = frames[0].size; let desired = size.x.max(size.y); desired.min(regions.first.x).min(regions.first.y) }; pod.first = Size::splat(length); pod.expand = Spec::splat(true); frames = child.layout(ctx, &pod, styles)?; } } else { // The default size that a shape takes on if it has no child and // enough space. let mut size = Size::new(Length::pt(45.0), Length::pt(30.0)).min(regions.first); if is_quadratic(S) { let length = if regions.expand.x || regions.expand.y { let target = regions.expand.select(regions.first, Size::zero()); target.x.max(target.y) } else { size.x.min(size.y) }; size = Size::splat(length); } else { size = regions.expand.select(regions.first, size); } frames = vec![Arc::new(Frame::new(size))]; } let frame = Arc::make_mut(&mut frames[0]); // Add fill and/or stroke. let fill = styles.get(Self::FILL); let stroke = match styles.get(Self::STROKE) { Smart::Auto => fill.is_none().then(Stroke::default), Smart::Custom(stroke) => stroke.map(RawStroke::unwrap_or_default), }; if fill.is_some() || stroke.is_some() { let geometry = if is_round(S) { Geometry::Ellipse(frame.size) } else { Geometry::Rect(frame.size) }; let shape = Shape { geometry, fill, stroke }; frame.prepend(Point::zero(), Element::Shape(shape)); } // Apply link if it exists. if let Some(url) = styles.get(TextNode::LINK) { frame.link(url.clone()); } Ok(frames) } } /// A category of shape. pub type ShapeKind = usize; /// A rectangle with equal side lengths. const SQUARE: ShapeKind = 0; /// A quadrilateral with four right angles. const RECT: ShapeKind = 1; /// An ellipse with coinciding foci. const CIRCLE: ShapeKind = 2; /// A curve around two focal points. const ELLIPSE: ShapeKind = 3; /// Whether a shape kind is curvy. fn is_round(kind: ShapeKind) -> bool { matches!(kind, CIRCLE | ELLIPSE) } /// Whether a shape kind has equal side length. fn is_quadratic(kind: ShapeKind) -> bool { matches!(kind, SQUARE | CIRCLE) }