mozilla-central/servo/components/style/invalidation/element/invalidator.rs (file symbol)

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/* 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/. */
//! The struct that takes care of encapsulating all the logic on where and how
//! element styles need to be invalidated.
use crate::context::StackLimitChecker;
use crate::dom::{TElement, TNode, TShadowRoot};
use crate::invalidation::element::invalidation_map::{
Dependency, DependencyInvalidationKind, NormalDependencyInvalidationKind,
RelativeDependencyInvalidationKind,
};
use selectors::matching::matches_compound_selector_from;
use selectors::matching::{CompoundSelectorMatchingResult, MatchingContext};
use selectors::parser::{Combinator, Component};
use selectors::OpaqueElement;
use smallvec::SmallVec;
use std::fmt;
use std::fmt::Write;
struct SiblingInfo<E>
where
E: TElement,
{
affected: E,
prev_sibling: Option<E>,
next_sibling: Option<E>,
}
/// Traversal mapping for elements under consideration. It acts like a snapshot map,
/// though this only "maps" one element at most.
/// For general invalidations, this has no effect, especially since when
/// DOM mutates, the mutation's effect should not escape the subtree being mutated.
/// This is not the case for relative selectors, unfortunately, so we may end up
/// traversing a portion of the DOM tree that mutated. In case the mutation is removal,
/// its sibling relation is severed by the time the invalidation happens. This structure
/// recovers that relation. Note - it assumes that there is only one element under this
/// effect.
pub struct SiblingTraversalMap<E>
where
E: TElement,
{
info: Option<SiblingInfo<E>>,
}
impl<E> Default for SiblingTraversalMap<E>
where
E: TElement,
{
fn default() -> Self {
Self { info: None }
}
}
impl<E> SiblingTraversalMap<E>
where
E: TElement,
{
/// Create a new traversal map with the affected element.
pub fn new(affected: E, prev_sibling: Option<E>, next_sibling: Option<E>) -> Self {
Self {
info: Some(SiblingInfo {
affected,
prev_sibling,
next_sibling,
}),
}
}
/// Get the element's previous sibling element.
pub fn next_sibling_for(&self, element: &E) -> Option<E> {
if let Some(ref info) = self.info {
if *element == info.affected {
return info.next_sibling;
}
}
element.next_sibling_element()
}
/// Get the element's previous sibling element.
pub fn prev_sibling_for(&self, element: &E) -> Option<E> {
if let Some(ref info) = self.info {
if *element == info.affected {
return info.prev_sibling;
}
}
element.prev_sibling_element()
}
}
/// A trait to abstract the collection of invalidations for a given pass.
pub trait InvalidationProcessor<'a, 'b, E>
where
E: TElement,
{
/// Whether an invalidation that contains only a pseudo-element selector
/// like ::before or ::after triggers invalidation of the element that would
/// originate it.
fn invalidates_on_pseudo_element(&self) -> bool {
false
}
/// Whether the invalidation processor only cares about light-tree
/// descendants of a given element, that is, doesn't invalidate
/// pseudo-elements, NAC, shadow dom...
fn light_tree_only(&self) -> bool {
false
}
/// When a dependency from a :where or :is selector matches, it may still be
/// the case that we don't need to invalidate the full style. Consider the
/// case of:
///
/// div .foo:where(.bar *, .baz) .qux
///
/// We can get to the `*` part after a .bar class change, but you only need
/// to restyle the element if it also matches .foo.
///
/// Similarly, you only need to restyle .baz if the whole result of matching
/// the selector changes.
///
/// This function is called to check the result of matching the "outer"
/// dependency that we generate for the parent of the `:where` selector,
/// that is, in the case above it should match
/// `div .foo:where(.bar *, .baz)`.
///
/// Returning true unconditionally here is over-optimistic and may
/// over-invalidate.
fn check_outer_dependency(&mut self, dependency: &Dependency, element: E) -> bool;
/// The matching context that should be used to process invalidations.
fn matching_context(&mut self) -> &mut MatchingContext<'b, E::Impl>;
/// The traversal map that should be used to process invalidations.
fn sibling_traversal_map(&self) -> &SiblingTraversalMap<E>;
/// Collect invalidations for a given element's descendants and siblings.
///
/// Returns whether the element itself was invalidated.
fn collect_invalidations(
&mut self,
element: E,
self_invalidations: &mut InvalidationVector<'a>,
descendant_invalidations: &mut DescendantInvalidationLists<'a>,
sibling_invalidations: &mut InvalidationVector<'a>,
) -> bool;
/// Returns whether the invalidation process should process the descendants
/// of the given element.
fn should_process_descendants(&mut self, element: E) -> bool;
/// Executes an arbitrary action when the recursion limit is exceded (if
/// any).
fn recursion_limit_exceeded(&mut self, element: E);
/// Executes an action when `Self` is invalidated.
fn invalidated_self(&mut self, element: E);
/// Executes an action when `sibling` is invalidated as a sibling of
/// `of`.
fn invalidated_sibling(&mut self, sibling: E, of: E);
/// Executes an action when any descendant of `Self` is invalidated.
fn invalidated_descendants(&mut self, element: E, child: E);
/// Executes an action when an element in a relative selector is reached.
/// Lets the dependency to be borrowed for further processing out of the
/// invalidation traversal.
fn found_relative_selector_invalidation(
&mut self,
_element: E,
_kind: RelativeDependencyInvalidationKind,
_relative_dependency: &'a Dependency,
) {
debug_assert!(false, "Reached relative selector dependency");
}
}
/// Different invalidation lists for descendants.
#[derive(Debug, Default)]
pub struct DescendantInvalidationLists<'a> {
/// Invalidations for normal DOM children and pseudo-elements.
///
/// TODO(emilio): Having a list of invalidations just for pseudo-elements
/// may save some work here and there.
pub dom_descendants: InvalidationVector<'a>,
/// Invalidations for slotted children of an element.
pub slotted_descendants: InvalidationVector<'a>,
/// Invalidations for ::part()s of an element.
pub parts: InvalidationVector<'a>,
}
impl<'a> DescendantInvalidationLists<'a> {
fn is_empty(&self) -> bool {
self.dom_descendants.is_empty() &&
self.slotted_descendants.is_empty() &&
self.parts.is_empty()
}
}
/// The struct that takes care of encapsulating all the logic on where and how
/// element styles need to be invalidated.
pub struct TreeStyleInvalidator<'a, 'b, 'c, E, P: 'a>
where
'b: 'a,
E: TElement,
P: InvalidationProcessor<'b, 'c, E>,
{
element: E,
stack_limit_checker: Option<&'a StackLimitChecker>,
processor: &'a mut P,
_marker: std::marker::PhantomData<(&'b (), &'c ())>,
}
/// A vector of invalidations, optimized for small invalidation sets.
pub type InvalidationVector<'a> = SmallVec<[Invalidation<'a>; 10]>;
/// The kind of descendant invalidation we're processing.
#[derive(Clone, Copy, Debug, Eq, PartialEq)]
enum DescendantInvalidationKind {
/// A DOM descendant invalidation.
Dom,
/// A ::slotted() descendant invalidation.
Slotted,
/// A ::part() descendant invalidation.
Part,
}
/// The kind of invalidation we're processing.
///
/// We can use this to avoid pushing invalidations of the same kind to our
/// descendants or siblings.
#[derive(Clone, Copy, Debug, Eq, PartialEq)]
enum InvalidationKind {
Descendant(DescendantInvalidationKind),
Sibling,
}
/// An `Invalidation` is a complex selector that describes which elements,
/// relative to a current element we are processing, must be restyled.
#[derive(Clone)]
pub struct Invalidation<'a> {
/// The dependency that generated this invalidation.
///
/// Note that the offset inside the dependency is not really useful after
/// construction.
dependency: &'a Dependency,
/// The right shadow host from where the rule came from, if any.
///
/// This is needed to ensure that we match the selector with the right
/// state, as whether some selectors like :host and ::part() match depends
/// on it.
scope: Option<OpaqueElement>,
/// The offset of the selector pointing to a compound selector.
///
/// This order is a "parse order" offset, that is, zero is the leftmost part
/// of the selector written as parsed / serialized.
///
/// It is initialized from the offset from `dependency`.
offset: usize,
/// Whether the invalidation was already matched by any previous sibling or
/// ancestor.
///
/// If this is the case, we can avoid pushing invalidations generated by
/// this one if the generated invalidation is effective for all the siblings
/// or descendants after us.
matched_by_any_previous: bool,
}
impl<'a> Invalidation<'a> {
/// Create a new invalidation for matching a dependency.
pub fn new(dependency: &'a Dependency, scope: Option<OpaqueElement>) -> Self {
debug_assert!(
dependency.selector_offset == dependency.selector.len() + 1 ||
dependency.normal_invalidation_kind() !=
NormalDependencyInvalidationKind::Element,
"No point to this, if the dependency matched the element we should just invalidate it"
);
Self {
dependency,
scope,
// + 1 to go past the combinator.
offset: dependency.selector.len() + 1 - dependency.selector_offset,
matched_by_any_previous: false,
}
}
/// Whether this invalidation is effective for the next sibling or
/// descendant after us.
fn effective_for_next(&self) -> bool {
if self.offset == 0 {
return true;
}
// TODO(emilio): For pseudo-elements this should be mostly false, except
// for the weird pseudos in <input type="number">.
//
// We should be able to do better here!
match self
.dependency
.selector
.combinator_at_parse_order(self.offset - 1)
{
Combinator::Descendant | Combinator::LaterSibling | Combinator::PseudoElement => true,
Combinator::Part |
Combinator::SlotAssignment |
Combinator::NextSibling |
Combinator::Child => false,
}
}
fn kind(&self) -> InvalidationKind {
if self.offset == 0 {
return InvalidationKind::Descendant(DescendantInvalidationKind::Dom);
}
match self
.dependency
.selector
.combinator_at_parse_order(self.offset - 1)
{
Combinator::Child | Combinator::Descendant | Combinator::PseudoElement => {
InvalidationKind::Descendant(DescendantInvalidationKind::Dom)
},
Combinator::Part => InvalidationKind::Descendant(DescendantInvalidationKind::Part),
Combinator::SlotAssignment => {
InvalidationKind::Descendant(DescendantInvalidationKind::Slotted)
},
Combinator::NextSibling | Combinator::LaterSibling => InvalidationKind::Sibling,
}
}
}
impl<'a> fmt::Debug for Invalidation<'a> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
use cssparser::ToCss;
f.write_str("Invalidation(")?;
for component in self
.dependency
.selector
.iter_raw_parse_order_from(self.offset)
{
if matches!(*component, Component::Combinator(..)) {
break;
}
component.to_css(f)?;
}
f.write_char(')')
}
}
/// The result of processing a single invalidation for a given element.
struct SingleInvalidationResult {
/// Whether the element itself was invalidated.
invalidated_self: bool,
/// Whether the invalidation matched, either invalidating the element or
/// generating another invalidation.
matched: bool,
}
/// The result of a whole invalidation process for a given element.
pub struct InvalidationResult {
/// Whether the element itself was invalidated.
invalidated_self: bool,
/// Whether the element's descendants were invalidated.
invalidated_descendants: bool,
/// Whether the element's siblings were invalidated.
invalidated_siblings: bool,
}
impl InvalidationResult {
/// Create an emtpy result.
pub fn empty() -> Self {
Self {
invalidated_self: false,
invalidated_descendants: false,
invalidated_siblings: false,
}
}
/// Whether the invalidation has invalidate the element itself.
pub fn has_invalidated_self(&self) -> bool {
self.invalidated_self
}
/// Whether the invalidation has invalidate desendants.
pub fn has_invalidated_descendants(&self) -> bool {
self.invalidated_descendants
}
/// Whether the invalidation has invalidate siblings.
pub fn has_invalidated_siblings(&self) -> bool {
self.invalidated_siblings
}
}
impl<'a, 'b, 'c, E, P: 'a> TreeStyleInvalidator<'a, 'b, 'c, E, P>
where
'b: 'a,
E: TElement,
P: InvalidationProcessor<'b, 'c, E>,
{
/// Trivially constructs a new `TreeStyleInvalidator`.
pub fn new(
element: E,
stack_limit_checker: Option<&'a StackLimitChecker>,
processor: &'a mut P,
) -> Self {
Self {
element,
stack_limit_checker,
processor,
_marker: std::marker::PhantomData,
}
}
/// Perform the invalidation pass.
pub fn invalidate(mut self) -> InvalidationResult {
debug!("StyleTreeInvalidator::invalidate({:?})", self.element);
let mut self_invalidations = InvalidationVector::new();
let mut descendant_invalidations = DescendantInvalidationLists::default();
let mut sibling_invalidations = InvalidationVector::new();
let mut invalidated_self = self.processor.collect_invalidations(
self.element,
&mut self_invalidations,
&mut descendant_invalidations,
&mut sibling_invalidations,
);
debug!("Collected invalidations (self: {}): ", invalidated_self);
debug!(
" > self: {}, {:?}",
self_invalidations.len(),
self_invalidations
);
debug!(" > descendants: {:?}", descendant_invalidations);
debug!(
" > siblings: {}, {:?}",
sibling_invalidations.len(),
sibling_invalidations
);
let invalidated_self_from_collection = invalidated_self;
invalidated_self |= self.process_descendant_invalidations(
&self_invalidations,
&mut descendant_invalidations,
&mut sibling_invalidations,
DescendantInvalidationKind::Dom,
);
if invalidated_self && !invalidated_self_from_collection {
self.processor.invalidated_self(self.element);
}
let invalidated_descendants = self.invalidate_descendants(&descendant_invalidations);
let invalidated_siblings = self.invalidate_siblings(&mut sibling_invalidations);
InvalidationResult {
invalidated_self,
invalidated_descendants,
invalidated_siblings,
}
}
/// Go through later DOM siblings, invalidating style as needed using the
/// `sibling_invalidations` list.
///
/// Returns whether any sibling's style or any sibling descendant's style
/// was invalidated.
fn invalidate_siblings(&mut self, sibling_invalidations: &mut InvalidationVector<'b>) -> bool {
if sibling_invalidations.is_empty() {
return false;
}
let mut current = self
.processor
.sibling_traversal_map()
.next_sibling_for(&self.element);
let mut any_invalidated = false;
while let Some(sibling) = current {
let mut sibling_invalidator =
TreeStyleInvalidator::new(sibling, self.stack_limit_checker, self.processor);
let mut invalidations_for_descendants = DescendantInvalidationLists::default();
let invalidated_sibling = sibling_invalidator.process_sibling_invalidations(
&mut invalidations_for_descendants,
sibling_invalidations,
);
if invalidated_sibling {
sibling_invalidator
.processor
.invalidated_sibling(sibling, self.element);
}
any_invalidated |= invalidated_sibling;
any_invalidated |=
sibling_invalidator.invalidate_descendants(&invalidations_for_descendants);
if sibling_invalidations.is_empty() {
break;
}
current = self
.processor
.sibling_traversal_map()
.next_sibling_for(&sibling);
}
any_invalidated
}
fn invalidate_pseudo_element_or_nac(
&mut self,
child: E,
invalidations: &[Invalidation<'b>],
) -> bool {
let mut sibling_invalidations = InvalidationVector::new();
let result = self.invalidate_child(
child,
invalidations,
&mut sibling_invalidations,
DescendantInvalidationKind::Dom,
);
// Roots of NAC subtrees can indeed generate sibling invalidations, but
// they can be just ignored, since they have no siblings.
//
// Note that we can end up testing selectors that wouldn't end up
// matching due to this being NAC, like those coming from document
// rules, but we overinvalidate instead of checking this.
result
}
/// Invalidate a child and recurse down invalidating its descendants if
/// needed.
fn invalidate_child(
&mut self,
child: E,
invalidations: &[Invalidation<'b>],
sibling_invalidations: &mut InvalidationVector<'b>,
descendant_invalidation_kind: DescendantInvalidationKind,
) -> bool {
let mut invalidations_for_descendants = DescendantInvalidationLists::default();
let mut invalidated_child = false;
let invalidated_descendants = {
let mut child_invalidator =
TreeStyleInvalidator::new(child, self.stack_limit_checker, self.processor);
invalidated_child |= child_invalidator.process_sibling_invalidations(
&mut invalidations_for_descendants,
sibling_invalidations,
);
invalidated_child |= child_invalidator.process_descendant_invalidations(
invalidations,
&mut invalidations_for_descendants,
sibling_invalidations,
descendant_invalidation_kind,
);
if invalidated_child {
child_invalidator.processor.invalidated_self(child);
}
child_invalidator.invalidate_descendants(&invalidations_for_descendants)
};
// The child may not be a flattened tree child of the current element,
// but may be arbitrarily deep.
//
// Since we keep the traversal flags in terms of the flattened tree,
// we need to propagate it as appropriate.
if invalidated_child || invalidated_descendants {
self.processor.invalidated_descendants(self.element, child);
}
invalidated_child || invalidated_descendants
}
fn invalidate_nac(&mut self, invalidations: &[Invalidation<'b>]) -> bool {
let mut any_nac_root = false;
let element = self.element;
element.each_anonymous_content_child(|nac| {
any_nac_root |= self.invalidate_pseudo_element_or_nac(nac, invalidations);
});
any_nac_root
}
// NB: It's important that this operates on DOM children, which is what
// selector-matching operates on.
fn invalidate_dom_descendants_of(
&mut self,
parent: E::ConcreteNode,
invalidations: &[Invalidation<'b>],
) -> bool {
let mut any_descendant = false;
let mut sibling_invalidations = InvalidationVector::new();
for child in parent.dom_children() {
let child = match child.as_element() {
Some(e) => e,
None => continue,
};
any_descendant |= self.invalidate_child(
child,
invalidations,
&mut sibling_invalidations,
DescendantInvalidationKind::Dom,
);
}
any_descendant
}
fn invalidate_parts_in_shadow_tree(
&mut self,
shadow: <E::ConcreteNode as TNode>::ConcreteShadowRoot,
invalidations: &[Invalidation<'b>],
) -> bool {
debug_assert!(!invalidations.is_empty());
let mut any = false;
let mut sibling_invalidations = InvalidationVector::new();
for node in shadow.as_node().dom_descendants() {
let element = match node.as_element() {
Some(e) => e,
None => continue,
};
if element.has_part_attr() {
any |= self.invalidate_child(
element,
invalidations,
&mut sibling_invalidations,
DescendantInvalidationKind::Part,
);
debug_assert!(
sibling_invalidations.is_empty(),
"::part() shouldn't have sibling combinators to the right, \
this makes no sense! {:?}",
sibling_invalidations
);
}
if let Some(shadow) = element.shadow_root() {
if element.exports_any_part() {
any |= self.invalidate_parts_in_shadow_tree(shadow, invalidations)
}
}
}
any
}
fn invalidate_parts(&mut self, invalidations: &[Invalidation<'b>]) -> bool {
if invalidations.is_empty() {
return false;
}
let shadow = match self.element.shadow_root() {
Some(s) => s,
None => return false,
};
self.invalidate_parts_in_shadow_tree(shadow, invalidations)
}
fn invalidate_slotted_elements(&mut self, invalidations: &[Invalidation<'b>]) -> bool {
if invalidations.is_empty() {
return false;
}
let slot = self.element;
self.invalidate_slotted_elements_in_slot(slot, invalidations)
}
fn invalidate_slotted_elements_in_slot(
&mut self,
slot: E,
invalidations: &[Invalidation<'b>],
) -> bool {
let mut any = false;
let mut sibling_invalidations = InvalidationVector::new();
for node in slot.slotted_nodes() {
let element = match node.as_element() {
Some(e) => e,
None => continue,
};
if element.is_html_slot_element() {
any |= self.invalidate_slotted_elements_in_slot(element, invalidations);
} else {
any |= self.invalidate_child(
element,
invalidations,
&mut sibling_invalidations,
DescendantInvalidationKind::Slotted,
);
}
debug_assert!(
sibling_invalidations.is_empty(),
"::slotted() shouldn't have sibling combinators to the right, \
this makes no sense! {:?}",
sibling_invalidations
);
}
any
}
fn invalidate_non_slotted_descendants(&mut self, invalidations: &[Invalidation<'b>]) -> bool {
if invalidations.is_empty() {
return false;
}
if self.processor.light_tree_only() {
let node = self.element.as_node();
return self.invalidate_dom_descendants_of(node, invalidations);
}
let mut any_descendant = false;
// NOTE(emilio): This is only needed for Shadow DOM to invalidate
// correctly on :host(..) changes. Instead of doing this, we could add
// a third kind of invalidation list that walks shadow root children,
// but it's not clear it's worth it.
//
// Also, it's needed as of right now for document state invalidation,
// where we rely on iterating every element that ends up in the composed
// doc, but we could fix that invalidating per subtree.
if let Some(root) = self.element.shadow_root() {
any_descendant |= self.invalidate_dom_descendants_of(root.as_node(), invalidations);
}
if let Some(marker) = self.element.marker_pseudo_element() {
any_descendant |= self.invalidate_pseudo_element_or_nac(marker, invalidations);
}
if let Some(before) = self.element.before_pseudo_element() {
any_descendant |= self.invalidate_pseudo_element_or_nac(before, invalidations);
}
let node = self.element.as_node();
any_descendant |= self.invalidate_dom_descendants_of(node, invalidations);
if let Some(after) = self.element.after_pseudo_element() {
any_descendant |= self.invalidate_pseudo_element_or_nac(after, invalidations);
}
any_descendant |= self.invalidate_nac(invalidations);
any_descendant
}
/// Given the descendant invalidation lists, go through the current
/// element's descendants, and invalidate style on them.
fn invalidate_descendants(&mut self, invalidations: &DescendantInvalidationLists<'b>) -> bool {
if invalidations.is_empty() {
return false;
}
debug!(
"StyleTreeInvalidator::invalidate_descendants({:?})",
self.element
);
debug!(" > {:?}", invalidations);
let should_process = self.processor.should_process_descendants(self.element);
if !should_process {
return false;
}
if let Some(checker) = self.stack_limit_checker {
if checker.limit_exceeded() {
self.processor.recursion_limit_exceeded(self.element);
return true;
}
}
let mut any_descendant = false;
any_descendant |= self.invalidate_non_slotted_descendants(&invalidations.dom_descendants);
any_descendant |= self.invalidate_slotted_elements(&invalidations.slotted_descendants);
any_descendant |= self.invalidate_parts(&invalidations.parts);
any_descendant
}
/// Process the given sibling invalidations coming from our previous
/// sibling.
///
/// The sibling invalidations are somewhat special because they can be
/// modified on the fly. New invalidations may be added and removed.
///
/// In particular, all descendants get the same set of invalidations from
/// the parent, but the invalidations from a given sibling depend on the
/// ones we got from the previous one.
///
/// Returns whether invalidated the current element's style.
fn process_sibling_invalidations(
&mut self,
descendant_invalidations: &mut DescendantInvalidationLists<'b>,
sibling_invalidations: &mut InvalidationVector<'b>,
) -> bool {
let mut i = 0;
let mut new_sibling_invalidations = InvalidationVector::new();
let mut invalidated_self = false;
while i < sibling_invalidations.len() {
let result = self.process_invalidation(
&sibling_invalidations[i],
descendant_invalidations,
&mut new_sibling_invalidations,
InvalidationKind::Sibling,
);
invalidated_self |= result.invalidated_self;
sibling_invalidations[i].matched_by_any_previous |= result.matched;
if sibling_invalidations[i].effective_for_next() {
i += 1;
} else {
sibling_invalidations.remove(i);
}
}
sibling_invalidations.extend(new_sibling_invalidations.drain(..));
invalidated_self
}
/// Process a given invalidation list coming from our parent,
/// adding to `descendant_invalidations` and `sibling_invalidations` as
/// needed.
///
/// Returns whether our style was invalidated as a result.
fn process_descendant_invalidations(
&mut self,
invalidations: &[Invalidation<'b>],
descendant_invalidations: &mut DescendantInvalidationLists<'b>,
sibling_invalidations: &mut InvalidationVector<'b>,
descendant_invalidation_kind: DescendantInvalidationKind,
) -> bool {
let mut invalidated = false;
for invalidation in invalidations {
let result = self.process_invalidation(
invalidation,
descendant_invalidations,
sibling_invalidations,
InvalidationKind::Descendant(descendant_invalidation_kind),
);
invalidated |= result.invalidated_self;
if invalidation.effective_for_next() {
let mut invalidation = invalidation.clone();
invalidation.matched_by_any_previous |= result.matched;
debug_assert_eq!(
descendant_invalidation_kind,
DescendantInvalidationKind::Dom,
"Slotted or part invalidations don't propagate."
);
descendant_invalidations.dom_descendants.push(invalidation);
}
}
invalidated
}
/// Processes a given invalidation, potentially invalidating the style of
/// the current element.
///
/// Returns whether invalidated the style of the element, and whether the
/// invalidation should be effective to subsequent siblings or descendants
/// down in the tree.
fn process_invalidation(
&mut self,
invalidation: &Invalidation<'b>,
descendant_invalidations: &mut DescendantInvalidationLists<'b>,
sibling_invalidations: &mut InvalidationVector<'b>,
invalidation_kind: InvalidationKind,
) -> SingleInvalidationResult {
debug!(
"TreeStyleInvalidator::process_invalidation({:?}, {:?}, {:?})",
self.element, invalidation, invalidation_kind
);
let matching_result = {
let context = self.processor.matching_context();
context.current_host = invalidation.scope;
matches_compound_selector_from(
&invalidation.dependency.selector,
invalidation.offset,
context,
&self.element,
)
};
let next_invalidation = match matching_result {
CompoundSelectorMatchingResult::NotMatched => {
return SingleInvalidationResult {
invalidated_self: false,
matched: false,
}
},
CompoundSelectorMatchingResult::FullyMatched => {
debug!(" > Invalidation matched completely");
// We matched completely. If we're an inner selector now we need
// to go outside our selector and carry on invalidating.
let mut cur_dependency = invalidation.dependency;
loop {
cur_dependency = match cur_dependency.parent {
None => {
return SingleInvalidationResult {
invalidated_self: true,
matched: true,
}
},
Some(ref p) => {
let invalidation_kind = p.invalidation_kind();
match invalidation_kind {
DependencyInvalidationKind::Normal(_) => &**p,
DependencyInvalidationKind::Relative(kind) => {
self.processor.found_relative_selector_invalidation(
self.element,
kind,
&**p,
);
return SingleInvalidationResult {
invalidated_self: false,
matched: true,
};
},
}
},
};
debug!(" > Checking outer dependency {:?}", cur_dependency);
// The inner selector changed, now check if the full
// previous part of the selector did, before keeping
// checking for descendants.
if !self
.processor
.check_outer_dependency(cur_dependency, self.element)
{
return SingleInvalidationResult {
invalidated_self: false,
matched: false,
};
}
if cur_dependency.normal_invalidation_kind() ==
NormalDependencyInvalidationKind::Element
{
continue;
}
debug!(" > Generating invalidation");
break Invalidation::new(cur_dependency, invalidation.scope);
}
},
CompoundSelectorMatchingResult::Matched {
next_combinator_offset,
} => Invalidation {
dependency: invalidation.dependency,
scope: invalidation.scope,
offset: next_combinator_offset + 1,
matched_by_any_previous: false,
},
};
debug_assert_ne!(
next_invalidation.offset, 0,
"Rightmost selectors shouldn't generate more invalidations",
);
let mut invalidated_self = false;
let next_combinator = next_invalidation
.dependency
.selector
.combinator_at_parse_order(next_invalidation.offset - 1);
if matches!(next_combinator, Combinator::PseudoElement) &&
self.processor.invalidates_on_pseudo_element()
{
// We need to invalidate the element whenever pseudos change, for
// two reasons:
//
// * Eager pseudo styles are stored as part of the originating
// element's computed style.
//
// * Lazy pseudo-styles might be cached on the originating
// element's pseudo-style cache.
//
// This could be more fine-grained (perhaps with a RESTYLE_PSEUDOS
// hint?).
//
// Note that we'll also restyle the pseudo-element because it would
// match this invalidation.
//
// FIXME: For non-element-backed pseudos this is still not quite
// correct. For example for ::selection even though we invalidate
// the style properly there's nothing that triggers a repaint
// necessarily. Though this matches old Gecko behavior, and the
// ::selection implementation needs to change significantly anyway
// example.
invalidated_self = true;
}
debug!(
" > Invalidation matched, next: {:?}, ({:?})",
next_invalidation, next_combinator
);
let next_invalidation_kind = next_invalidation.kind();
// We can skip pushing under some circumstances, and we should
// because otherwise the invalidation list could grow
// exponentially.
//
// * First of all, both invalidations need to be of the same
// kind. This is because of how we propagate them going to
// the right of the tree for sibling invalidations and going
// down the tree for children invalidations. A sibling
// invalidation that ends up generating a children
// invalidation ends up (correctly) in five different lists,
// not in the same list five different times.
//
// * Then, the invalidation needs to be matched by a previous
// ancestor/sibling, in order to know that this invalidation
// has been generated already.
//
// * Finally, the new invalidation needs to be
// `effective_for_next()`, in order for us to know that it is
// still in the list, since we remove the dependencies that
// aren't from the lists for our children / siblings.
//
// To go through an example, let's imagine we are processing a
// dom subtree like:
//
// <div><address><div><div/></div></address></div>
//
// And an invalidation list with a single invalidation like:
//
// [div div div]
//
// When we process the invalidation list for the outer div, we
// match it, and generate a `div div` invalidation, so for the
// <address> child we have:
//
// [div div div, div div]
//
// With the first of them marked as `matched`.
//
// When we process the <address> child, we don't match any of
// them, so both invalidations go untouched to our children.
//
// When we process the second <div>, we match _both_
// invalidations.
//
// However, when matching the first, we can tell it's been
// matched, and not push the corresponding `div div`
// invalidation, since we know it's necessarily already on the
// list.
//
// Thus, without skipping the push, we'll arrive to the
// innermost <div> with:
//
// [div div div, div div, div div, div]
//
// While skipping it, we won't arrive here with duplicating
// dependencies:
//
// [div div div, div div, div]
//
let can_skip_pushing = next_invalidation_kind == invalidation_kind &&
invalidation.matched_by_any_previous &&
next_invalidation.effective_for_next();
if can_skip_pushing {
debug!(
" > Can avoid push, since the invalidation had \
already been matched before"
);
} else {
match next_invalidation_kind {
InvalidationKind::Descendant(DescendantInvalidationKind::Dom) => {
descendant_invalidations
.dom_descendants
.push(next_invalidation);
},
InvalidationKind::Descendant(DescendantInvalidationKind::Part) => {
descendant_invalidations.parts.push(next_invalidation);
},
InvalidationKind::Descendant(DescendantInvalidationKind::Slotted) => {
descendant_invalidations
.slotted_descendants
.push(next_invalidation);
},
InvalidationKind::Sibling => {
sibling_invalidations.push(next_invalidation);
},
}
}
SingleInvalidationResult {
invalidated_self,
matched: true,
}
}
}