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|
//! Side-by-side layout of nodes along an axis.
use super::prelude::*;
use super::{AlignNode, SpacingKind};
/// Arrange nodes and spacing along an axis.
#[derive(Debug, Hash)]
pub struct StackNode {
/// The stacking direction.
pub dir: Dir,
/// The spacing between non-spacing children.
pub spacing: Option<SpacingKind>,
/// The children to be stacked.
pub children: Vec<StackChild>,
}
#[class]
impl StackNode {
fn construct(_: &mut Vm, args: &mut Args) -> TypResult<Template> {
Ok(Template::block(Self {
dir: args.named("dir")?.unwrap_or(Dir::TTB),
spacing: args.named("spacing")?,
children: args.all()?,
}))
}
}
impl Layout for StackNode {
fn layout(
&self,
vm: &mut Vm,
regions: &Regions,
styles: StyleChain,
) -> TypResult<Vec<Arc<Frame>>> {
let mut layouter = StackLayouter::new(self.dir, regions);
// Spacing to insert before the next node.
let mut deferred = None;
for child in &self.children {
match child {
StackChild::Spacing(kind) => {
layouter.layout_spacing(*kind);
deferred = None;
}
StackChild::Node(node) => {
if let Some(kind) = deferred {
layouter.layout_spacing(kind);
}
layouter.layout_node(vm, node, styles)?;
deferred = self.spacing;
}
}
}
Ok(layouter.finish())
}
}
/// A child of a stack node.
#[derive(Hash)]
pub enum StackChild {
/// Spacing between other nodes.
Spacing(SpacingKind),
/// An arbitrary node.
Node(LayoutNode),
}
impl Debug for StackChild {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
Self::Spacing(kind) => kind.fmt(f),
Self::Node(node) => node.fmt(f),
}
}
}
castable! {
StackChild,
Expected: "linear, fractional or template",
Value::Length(v) => Self::Spacing(SpacingKind::Linear(v.into())),
Value::Relative(v) => Self::Spacing(SpacingKind::Linear(v.into())),
Value::Linear(v) => Self::Spacing(SpacingKind::Linear(v)),
Value::Fractional(v) => Self::Spacing(SpacingKind::Fractional(v)),
Value::Template(v) => Self::Node(v.pack()),
}
/// Performs stack layout.
pub struct StackLayouter {
/// The stacking direction.
dir: Dir,
/// The axis of the stacking direction.
axis: SpecAxis,
/// The regions to layout children into.
regions: Regions,
/// Whether the stack itself should expand to fill the region.
expand: Spec<bool>,
/// The full size of the current region that was available at the start.
full: Size,
/// The generic size used by the frames for the current region.
used: Gen<Length>,
/// The sum of fractional ratios in the current region.
fr: Fractional,
/// Already layouted items whose exact positions are not yet known due to
/// fractional spacing.
items: Vec<StackItem>,
/// Finished frames for previous regions.
finished: Vec<Arc<Frame>>,
}
/// A prepared item in a stack layout.
enum StackItem {
/// Absolute spacing between other items.
Absolute(Length),
/// Fractional spacing between other items.
Fractional(Fractional),
/// A frame for a layouted child node.
Frame(Arc<Frame>, Align),
}
impl StackLayouter {
/// Create a new stack layouter.
pub fn new(dir: Dir, regions: &Regions) -> Self {
let axis = dir.axis();
let expand = regions.expand;
let full = regions.first;
// Disable expansion along the block axis for children.
let mut regions = regions.clone();
regions.expand.set(axis, false);
Self {
dir,
axis,
regions,
expand,
full,
used: Gen::zero(),
fr: Fractional::zero(),
items: vec![],
finished: vec![],
}
}
/// Add spacing along the spacing direction.
pub fn layout_spacing(&mut self, spacing: SpacingKind) {
match spacing {
SpacingKind::Linear(v) => {
// Resolve the linear and limit it to the remaining space.
let resolved = v.resolve(self.regions.base.get(self.axis));
let remaining = self.regions.first.get_mut(self.axis);
let limited = resolved.min(*remaining);
*remaining -= limited;
self.used.main += limited;
self.items.push(StackItem::Absolute(resolved));
}
SpacingKind::Fractional(v) => {
self.fr += v;
self.items.push(StackItem::Fractional(v));
}
}
}
/// Layout an arbitrary node.
pub fn layout_node(
&mut self,
vm: &mut Vm,
node: &LayoutNode,
styles: StyleChain,
) -> TypResult<()> {
if self.regions.is_full() {
self.finish_region();
}
// Align nodes' block-axis alignment is respected by the stack node.
let align = node
.downcast::<AlignNode>()
.and_then(|node| node.aligns.get(self.axis))
.unwrap_or(self.dir.start().into());
let frames = node.layout(vm, &self.regions, styles)?;
let len = frames.len();
for (i, frame) in frames.into_iter().enumerate() {
// Grow our size, shrink the region and save the frame for later.
let size = frame.size.to_gen(self.axis);
self.used.main += size.main;
self.used.cross.set_max(size.cross);
*self.regions.first.get_mut(self.axis) -= size.main;
self.items.push(StackItem::Frame(frame, align));
if i + 1 < len {
self.finish_region();
}
}
Ok(())
}
/// Advance to the next region.
pub fn finish_region(&mut self) {
// Determine the size of the stack in this region dependening on whether
// the region expands.
let used = self.used.to_spec(self.axis);
let mut size = self.expand.select(self.full, used);
// Expand fully if there are fr spacings.
let full = self.full.get(self.axis);
let remaining = full - self.used.main;
if self.fr.get() > 0.0 && full.is_finite() {
self.used.main = full;
size.set(self.axis, full);
}
let mut output = Frame::new(size);
let mut cursor = Length::zero();
let mut ruler: Align = self.dir.start().into();
// Place all frames.
for item in self.items.drain(..) {
match item {
StackItem::Absolute(v) => cursor += v,
StackItem::Fractional(v) => cursor += v.resolve(self.fr, remaining),
StackItem::Frame(frame, align) => {
if self.dir.is_positive() {
ruler = ruler.max(align);
} else {
ruler = ruler.min(align);
}
// Align along the block axis.
let parent = size.get(self.axis);
let child = frame.size.get(self.axis);
let block = ruler.resolve(parent - self.used.main)
+ if self.dir.is_positive() {
cursor
} else {
self.used.main - child - cursor
};
let pos = Gen::new(Length::zero(), block).to_point(self.axis);
cursor += child;
output.push_frame(pos, frame);
}
}
}
// Advance to the next region.
self.regions.next();
self.full = self.regions.first;
self.used = Gen::zero();
self.fr = Fractional::zero();
self.finished.push(Arc::new(output));
}
/// Finish layouting and return the resulting frames.
pub fn finish(mut self) -> Vec<Arc<Frame>> {
self.finish_region();
self.finished
}
}
|
