/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at https://mozilla.org/MPL/2.0/. */ //! Traversals over the DOM and flow trees, running the layout computations. use crate::construct::FlowConstructor; use crate::context::LayoutContext; use crate::display_list::DisplayListBuildState; use crate::flow::{Flow, FlowFlags, GetBaseFlow, ImmutableFlowUtils}; use crate::wrapper::ThreadSafeLayoutNodeHelpers; use crate::wrapper::{GetRawData, LayoutNodeLayoutData}; use script_layout_interface::wrapper_traits::{LayoutNode, ThreadSafeLayoutNode}; use servo_config::opts; use style::context::{SharedStyleContext, StyleContext}; use style::data::ElementData; use style::dom::{NodeInfo, TElement, TNode}; use style::selector_parser::RestyleDamage; use style::servo::restyle_damage::ServoRestyleDamage; use style::traversal::PerLevelTraversalData; use style::traversal::{recalc_style_at, DomTraversal}; pub struct RecalcStyleAndConstructFlows<'a> { context: LayoutContext<'a>, } impl<'a> RecalcStyleAndConstructFlows<'a> { /// Creates a traversal context, taking ownership of the shared layout context. pub fn new(context: LayoutContext<'a>) -> Self { RecalcStyleAndConstructFlows { context: context } } /// Consumes this traversal context, returning ownership of the shared layout /// context to the caller. pub fn destroy(self) -> LayoutContext<'a> { self.context } } #[allow(unsafe_code)] impl<'a, E> DomTraversal for RecalcStyleAndConstructFlows<'a> where E: TElement, E::ConcreteNode: LayoutNode, E::FontMetricsProvider: Send, { fn process_preorder( &self, traversal_data: &PerLevelTraversalData, context: &mut StyleContext, node: E::ConcreteNode, note_child: F, ) where F: FnMut(E::ConcreteNode), { // FIXME(pcwalton): Stop allocating here. Ideally this should just be // done by the HTML parser. unsafe { node.initialize_data() }; if !node.is_text_node() { let el = node.as_element().unwrap(); let mut data = el.mutate_data().unwrap(); recalc_style_at(self, traversal_data, context, el, &mut data, note_child); } } fn process_postorder(&self, _style_context: &mut StyleContext, node: E::ConcreteNode) { construct_flows_at(&self.context, node); } fn text_node_needs_traversal(node: E::ConcreteNode, parent_data: &ElementData) -> bool { // Text nodes never need styling. However, there are two cases they may need // flow construction: // (1) They child doesn't yet have layout data (preorder traversal initializes it). // (2) The parent element has restyle damage (so the text flow also needs fixup). node.get_raw_data().is_none() || !parent_data.damage.is_empty() } fn shared_context(&self) -> &SharedStyleContext { &self.context.style_context } } /// A top-down traversal. pub trait PreorderFlowTraversal { /// The operation to perform. Return true to continue or false to stop. fn process(&self, flow: &mut dyn Flow); /// Returns true if this node should be processed and false if neither this node nor its /// descendants should be processed. fn should_process_subtree(&self, _flow: &mut dyn Flow) -> bool { true } /// Returns true if this node must be processed in-order. If this returns false, /// we skip the operation for this node, but continue processing the descendants. /// This is called *after* parent nodes are visited. fn should_process(&self, _flow: &mut dyn Flow) -> bool { true } /// Traverses the tree in preorder. fn traverse(&self, flow: &mut dyn Flow) { if !self.should_process_subtree(flow) { return; } if self.should_process(flow) { self.process(flow); } for kid in flow.mut_base().child_iter_mut() { self.traverse(kid); } } /// Traverse the Absolute flow tree in preorder. /// /// Traverse all your direct absolute descendants, who will then traverse /// their direct absolute descendants. /// /// Return true if the traversal is to continue or false to stop. fn traverse_absolute_flows(&self, flow: &mut dyn Flow) { if self.should_process(flow) { self.process(flow); } for descendant_link in flow.mut_base().abs_descendants.iter() { self.traverse_absolute_flows(descendant_link) } } } /// A bottom-up traversal, with a optional in-order pass. pub trait PostorderFlowTraversal { /// The operation to perform. Return true to continue or false to stop. fn process(&self, flow: &mut dyn Flow); /// Returns false if this node must be processed in-order. If this returns false, we skip the /// operation for this node, but continue processing the ancestors. This is called *after* /// child nodes are visited. fn should_process(&self, _flow: &mut dyn Flow) -> bool { true } /// Traverses the tree in postorder. fn traverse(&self, flow: &mut dyn Flow) { for kid in flow.mut_base().child_iter_mut() { self.traverse(kid); } if self.should_process(flow) { self.process(flow); } } } /// An in-order (sequential only) traversal. pub trait InorderFlowTraversal { /// The operation to perform. Returns the level of the tree we're at. fn process(&mut self, flow: &mut dyn Flow, level: u32); /// Returns true if this node should be processed and false if neither this node nor its /// descendants should be processed. fn should_process_subtree(&mut self, _flow: &mut dyn Flow) -> bool { true } /// Traverses the tree in-order. fn traverse(&mut self, flow: &mut dyn Flow, level: u32) { if !self.should_process_subtree(flow) { return; } self.process(flow, level); for kid in flow.mut_base().child_iter_mut() { self.traverse(kid, level + 1); } } } /// A bottom-up, parallelizable traversal. pub trait PostorderNodeMutTraversal { /// The operation to perform. Return true to continue or false to stop. fn process(&mut self, node: &ConcreteThreadSafeLayoutNode); } /// The flow construction traversal, which builds flows for styled nodes. #[inline] #[allow(unsafe_code)] fn construct_flows_at(context: &LayoutContext, node: N) where N: LayoutNode, { debug!("construct_flows_at: {:?}", node); // Construct flows for this node. { let tnode = node.to_threadsafe(); // Always reconstruct if incremental layout is turned off. let nonincremental_layout = opts::get().nonincremental_layout; if nonincremental_layout || tnode.restyle_damage() != RestyleDamage::empty() || node.as_element() .map_or(false, |el| el.has_dirty_descendants()) { let mut flow_constructor = FlowConstructor::new(context); if nonincremental_layout || !flow_constructor.repair_if_possible(&tnode) { flow_constructor.process(&tnode); debug!( "Constructed flow for {:?}: {:x}", tnode, tnode.flow_debug_id() ); } } tnode .mutate_layout_data() .unwrap() .flags .insert(crate::data::LayoutDataFlags::HAS_BEEN_TRAVERSED); } if let Some(el) = node.as_element() { unsafe { el.unset_dirty_descendants(); } } } /// The bubble-inline-sizes traversal, the first part of layout computation. This computes /// preferred and intrinsic inline-sizes and bubbles them up the tree. pub struct BubbleISizes<'a> { pub layout_context: &'a LayoutContext<'a>, } impl<'a> PostorderFlowTraversal for BubbleISizes<'a> { #[inline] fn process(&self, flow: &mut dyn Flow) { flow.bubble_inline_sizes(); flow.mut_base() .restyle_damage .remove(ServoRestyleDamage::BUBBLE_ISIZES); } #[inline] fn should_process(&self, flow: &mut dyn Flow) -> bool { flow.base() .restyle_damage .contains(ServoRestyleDamage::BUBBLE_ISIZES) } } /// The assign-inline-sizes traversal. In Gecko this corresponds to `Reflow`. #[derive(Clone, Copy)] pub struct AssignISizes<'a> { pub layout_context: &'a LayoutContext<'a>, } impl<'a> PreorderFlowTraversal for AssignISizes<'a> { #[inline] fn process(&self, flow: &mut dyn Flow) { flow.assign_inline_sizes(self.layout_context); } #[inline] fn should_process(&self, flow: &mut dyn Flow) -> bool { flow.base() .restyle_damage .intersects(ServoRestyleDamage::REFLOW_OUT_OF_FLOW | ServoRestyleDamage::REFLOW) } } /// The assign-block-sizes-and-store-overflow traversal, the last (and most expensive) part of /// layout computation. Determines the final block-sizes for all layout objects and computes /// positions. In Gecko this corresponds to `Reflow`. #[derive(Clone, Copy)] pub struct AssignBSizes<'a> { pub layout_context: &'a LayoutContext<'a>, } impl<'a> PostorderFlowTraversal for AssignBSizes<'a> { #[inline] fn process(&self, flow: &mut dyn Flow) { // Can't do anything with anything that floats might flow through until we reach their // inorder parent. // // NB: We must return without resetting the restyle bits for these, as we haven't actually // reflowed anything! if flow.floats_might_flow_through() { return; } flow.assign_block_size(self.layout_context); } #[inline] fn should_process(&self, flow: &mut dyn Flow) -> bool { let base = flow.base(); base.restyle_damage.intersects(ServoRestyleDamage::REFLOW_OUT_OF_FLOW | ServoRestyleDamage::REFLOW) && // The fragmentation countainer is responsible for calling // Flow::fragment recursively !base.flags.contains(FlowFlags::CAN_BE_FRAGMENTED) } } pub struct ComputeStackingRelativePositions<'a> { pub layout_context: &'a LayoutContext<'a>, } impl<'a> PreorderFlowTraversal for ComputeStackingRelativePositions<'a> { #[inline] fn should_process_subtree(&self, flow: &mut dyn Flow) -> bool { flow.base() .restyle_damage .contains(ServoRestyleDamage::REPOSITION) } #[inline] fn process(&self, flow: &mut dyn Flow) { flow.compute_stacking_relative_position(self.layout_context); flow.mut_base() .restyle_damage .remove(ServoRestyleDamage::REPOSITION) } } pub struct BuildDisplayList<'a> { pub state: DisplayListBuildState<'a>, } impl<'a> BuildDisplayList<'a> { #[inline] pub fn traverse(&mut self, flow: &mut dyn Flow) { let parent_stacking_context_id = self.state.current_stacking_context_id; self.state.current_stacking_context_id = flow.base().stacking_context_id; let parent_clipping_and_scrolling = self.state.current_clipping_and_scrolling; self.state.current_clipping_and_scrolling = flow.clipping_and_scrolling(); flow.build_display_list(&mut self.state); flow.mut_base() .restyle_damage .remove(ServoRestyleDamage::REPAINT); for kid in flow.mut_base().child_iter_mut() { self.traverse(kid); } self.state.current_stacking_context_id = parent_stacking_context_id; self.state.current_clipping_and_scrolling = parent_clipping_and_scrolling; } }