Magic-Mirror/gecko-dev
1
0
Fork 0
mirror of https://github.com/mozilla/gecko-dev.git synced 2024-10-20 16:55:40 +00:00
Code Issues Actions Packages Projects Releases Wiki Activity
351b329516
gecko-dev/servo/components/style/restyle_hints.rs
Bobby Holley 62e95664e4 servo: Merge #14300 - stylo: Basic infrastructure for RestyleHint-driven traversal (from bholley:restyle_driven_traversal); r=emilio 
Gecko Bug: https://bugzilla.mozilla.org/show_bug.cgi?id=131701

(Don't review yet, will flag on the gecko bug when the time comes)

Source-Repo: https://github.com/servo/servo
Source-Revision: d98abaec20e624aa89a3abddf4cf2a6399951ef1
2016-11-25 09:00:44 -08:00

513 lines
18 KiB
Rust
Raw Blame History

/* 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 http://mozilla.org/MPL/2.0/. */
//! Restyle hints: an optimization to avoid unnecessarily matching selectors.
use Atom;
use element_state::*;
#[cfg(feature = "gecko")]
use gecko_bindings::structs::nsRestyleHint;
#[cfg(feature = "servo")]
use heapsize::HeapSizeOf;
use selector_parser::{AttrValue, ElementExt, NonTSPseudoClass, Snapshot, SelectorImpl};
use selectors::{Element, MatchAttr};
use selectors::matching::{MatchingReason, StyleRelations};
use selectors::matching::matches_complex_selector;
use selectors::parser::{AttrSelector, Combinator, ComplexSelector, SimpleSelector};
use std::clone::Clone;
use std::sync::Arc;
/// When the ElementState of an element (like IN_HOVER_STATE) changes, certain
/// pseudo-classes (like :hover) may require us to restyle that element, its
/// siblings, and/or its descendants. Similarly, when various attributes of an
/// element change, we may also need to restyle things with id, class, and
/// attribute selectors. Doing this conservatively is expensive, and so we use
/// RestyleHints to short-circuit work we know is unnecessary.
bitflags! {
pub flags RestyleHint: u32 {
#[doc = "Rerun selector matching on the element."]
const RESTYLE_SELF = 0x01,
#[doc = "Rerun selector matching on all of the element's descendants."]
// NB: In Gecko, we have RESTYLE_SUBTREE which is inclusive of self, but heycam isn't aware
// of a good reason for that.
const RESTYLE_DESCENDANTS = 0x02,
#[doc = "Rerun selector matching on all later siblings of the element and all of their descendants."]
const RESTYLE_LATER_SIBLINGS = 0x08,
}
}
#[cfg(feature = "gecko")]
impl From<nsRestyleHint> for RestyleHint {
fn from(raw: nsRestyleHint) -> Self {
use std::mem;
let raw_bits: u32 = unsafe { mem::transmute(raw) };
// FIXME(bholley): Finish aligning the binary representations here and
// then .expect() the result of the checked version.
if Self::from_bits(raw_bits).is_none() {
error!("stylo: dropping unsupported restyle hint bits");
}
Self::from_bits_truncate(raw_bits)
}
}
#[cfg(feature = "servo")]
impl HeapSizeOf for RestyleHint {
fn heap_size_of_children(&self) -> usize { 0 }
}
/// In order to compute restyle hints, we perform a selector match against a
/// list of partial selectors whose rightmost simple selector may be sensitive
/// to the thing being changed. We do this matching twice, once for the element
/// as it exists now and once for the element as it existed at the time of the
/// last restyle. If the results of the selector match differ, that means that
/// the given partial selector is sensitive to the change, and we compute a
/// restyle hint based on its combinator.
///
/// In order to run selector matching against the old element state, we generate
/// a wrapper for the element which claims to have the old state. This is the
/// ElementWrapper logic below.
///
/// Gecko does this differently for element states, and passes a mask called
/// mStateMask, which indicates the states that need to be ignored during
/// selector matching. This saves an ElementWrapper allocation and an additional
/// selector match call at the expense of additional complexity inside the
/// selector matching logic. This only works for boolean states though, so we
/// still need to take the ElementWrapper approach for attribute-dependent
/// style. So we do it the same both ways for now to reduce complexity, but it's
/// worth measuring the performance impact (if any) of the mStateMask approach.
pub trait ElementSnapshot : Sized + MatchAttr<Impl=SelectorImpl> {
/// The state of the snapshot, if any.
fn state(&self) -> Option<ElementState>;
/// If this snapshot contains attribute information.
fn has_attrs(&self) -> bool;
/// The ID attribute per this snapshot. Should only be called if
/// `has_attrs()` returns true.
fn id_attr(&self) -> Option<Atom>;
/// Whether this snapshot contains the class `name`. Should only be called
/// if `has_attrs()` returns true.
fn has_class(&self, name: &Atom) -> bool;
/// A callback that should be called for each class of the snapshot. Should
/// only be called if `has_attrs()` returns true.
fn each_class<F>(&self, F)
where F: FnMut(&Atom);
}
struct ElementWrapper<'a, E>
where E: ElementExt
{
element: E,
snapshot: Option<&'a Snapshot>,
}
impl<'a, E> ElementWrapper<'a, E>
where E: ElementExt
{
pub fn new(el: E) -> ElementWrapper<'a, E> {
ElementWrapper { element: el, snapshot: None }
}
pub fn new_with_snapshot(el: E, snapshot: &'a Snapshot) -> ElementWrapper<'a, E> {
ElementWrapper { element: el, snapshot: Some(snapshot) }
}
}
impl<'a, E> MatchAttr for ElementWrapper<'a, E>
where E: ElementExt,
{
type Impl = SelectorImpl;
fn match_attr_has(&self, attr: &AttrSelector<SelectorImpl>) -> bool {
match self.snapshot {
Some(snapshot) if snapshot.has_attrs()
=> snapshot.match_attr_has(attr),
_ => self.element.match_attr_has(attr)
}
}
fn match_attr_equals(&self,
attr: &AttrSelector<SelectorImpl>,
value: &AttrValue) -> bool {
match self.snapshot {
Some(snapshot) if snapshot.has_attrs()
=> snapshot.match_attr_equals(attr, value),
_ => self.element.match_attr_equals(attr, value)
}
}
fn match_attr_equals_ignore_ascii_case(&self,
attr: &AttrSelector<SelectorImpl>,
value: &AttrValue) -> bool {
match self.snapshot {
Some(snapshot) if snapshot.has_attrs()
=> snapshot.match_attr_equals_ignore_ascii_case(attr, value),
_ => self.element.match_attr_equals_ignore_ascii_case(attr, value)
}
}
fn match_attr_includes(&self,
attr: &AttrSelector<SelectorImpl>,
value: &AttrValue) -> bool {
match self.snapshot {
Some(snapshot) if snapshot.has_attrs()
=> snapshot.match_attr_includes(attr, value),
_ => self.element.match_attr_includes(attr, value)
}
}
fn match_attr_dash(&self,
attr: &AttrSelector<SelectorImpl>,
value: &AttrValue) -> bool {
match self.snapshot {
Some(snapshot) if snapshot.has_attrs()
=> snapshot.match_attr_dash(attr, value),
_ => self.element.match_attr_dash(attr, value)
}
}
fn match_attr_prefix(&self,
attr: &AttrSelector<SelectorImpl>,
value: &AttrValue) -> bool {
match self.snapshot {
Some(snapshot) if snapshot.has_attrs()
=> snapshot.match_attr_prefix(attr, value),
_ => self.element.match_attr_prefix(attr, value)
}
}
fn match_attr_substring(&self,
attr: &AttrSelector<SelectorImpl>,
value: &AttrValue) -> bool {
match self.snapshot {
Some(snapshot) if snapshot.has_attrs()
=> snapshot.match_attr_substring(attr, value),
_ => self.element.match_attr_substring(attr, value)
}
}
fn match_attr_suffix(&self,
attr: &AttrSelector<SelectorImpl>,
value: &AttrValue) -> bool {
match self.snapshot {
Some(snapshot) if snapshot.has_attrs()
=> snapshot.match_attr_suffix(attr, value),
_ => self.element.match_attr_suffix(attr, value)
}
}
}
impl<'a, E> Element for ElementWrapper<'a, E>
where E: ElementExt<Impl=SelectorImpl>
{
fn match_non_ts_pseudo_class(&self, pseudo_class: NonTSPseudoClass) -> bool {
let flag = SelectorImpl::pseudo_class_state_flag(&pseudo_class);
if flag == ElementState::empty() {
self.element.match_non_ts_pseudo_class(pseudo_class)
} else {
match self.snapshot.and_then(|s| s.state()) {
Some(snapshot_state) => snapshot_state.contains(flag),
_ => self.element.match_non_ts_pseudo_class(pseudo_class)
}
}
}
fn parent_element(&self) -> Option<Self> {
self.element.parent_element().map(ElementWrapper::new)
}
fn first_child_element(&self) -> Option<Self> {
self.element.first_child_element().map(ElementWrapper::new)
}
fn last_child_element(&self) -> Option<Self> {
self.element.last_child_element().map(ElementWrapper::new)
}
fn prev_sibling_element(&self) -> Option<Self> {
self.element.prev_sibling_element().map(ElementWrapper::new)
}
fn next_sibling_element(&self) -> Option<Self> {
self.element.next_sibling_element().map(ElementWrapper::new)
}
fn is_html_element_in_html_document(&self) -> bool {
self.element.is_html_element_in_html_document()
}
fn get_local_name(&self) -> &<Self::Impl as ::selectors::SelectorImpl>::BorrowedLocalName {
self.element.get_local_name()
}
fn get_namespace(&self) -> &<Self::Impl as ::selectors::SelectorImpl>::BorrowedNamespaceUrl {
self.element.get_namespace()
}
fn get_id(&self) -> Option<Atom> {
match self.snapshot {
Some(snapshot) if snapshot.has_attrs()
=> snapshot.id_attr(),
_ => self.element.get_id()
}
}
fn has_class(&self, name: &Atom) -> bool {
match self.snapshot {
Some(snapshot) if snapshot.has_attrs()
=> snapshot.has_class(name),
_ => self.element.has_class(name)
}
}
fn is_empty(&self) -> bool {
self.element.is_empty()
}
fn is_root(&self) -> bool {
self.element.is_root()
}
fn each_class<F>(&self, callback: F)
where F: FnMut(&Atom) {
match self.snapshot {
Some(snapshot) if snapshot.has_attrs()
=> snapshot.each_class(callback),
_ => self.element.each_class(callback)
}
}
}
fn selector_to_state(sel: &SimpleSelector<SelectorImpl>) -> ElementState {
match *sel {
SimpleSelector::NonTSPseudoClass(ref pc) => SelectorImpl::pseudo_class_state_flag(pc),
_ => ElementState::empty(),
}
}
fn is_attr_selector(sel: &SimpleSelector<SelectorImpl>) -> bool {
match *sel {
SimpleSelector::ID(_) |
SimpleSelector::Class(_) |
SimpleSelector::AttrExists(_) |
SimpleSelector::AttrEqual(_, _, _) |
SimpleSelector::AttrIncludes(_, _) |
SimpleSelector::AttrDashMatch(_, _) |
SimpleSelector::AttrPrefixMatch(_, _) |
SimpleSelector::AttrSubstringMatch(_, _) |
SimpleSelector::AttrSuffixMatch(_, _) => true,
_ => false,
}
}
fn combinator_to_restyle_hint(combinator: Option<Combinator>) -> RestyleHint {
match combinator {
None => RESTYLE_SELF,
Some(c) => match c {
Combinator::Child => RESTYLE_DESCENDANTS,
Combinator::Descendant => RESTYLE_DESCENDANTS,
Combinator::NextSibling => RESTYLE_LATER_SIBLINGS,
Combinator::LaterSibling => RESTYLE_LATER_SIBLINGS,
}
}
}
#[derive(Debug)]
#[cfg_attr(feature = "servo", derive(HeapSizeOf))]
struct Sensitivities {
pub states: ElementState,
pub attrs: bool,
}
impl Sensitivities {
fn is_empty(&self) -> bool {
self.states.is_empty() && !self.attrs
}
fn new() -> Sensitivities {
Sensitivities {
states: ElementState::empty(),
attrs: false,
}
}
}
/// Mapping between (partial) CompoundSelectors (and the combinator to their
/// right) and the states and attributes they depend on.
///
/// In general, for all selectors in all applicable stylesheets of the form:
///
/// |a _ b _ c _ d _ e|
///
/// Where:
/// * |b| and |d| are simple selectors that depend on state (like :hover) or
/// attributes (like [attr...], .foo, or #foo).
/// * |a|, |c|, and |e| are arbitrary simple selectors that do not depend on
/// state or attributes.
///
/// We generate a Dependency for both |a _ b:X _| and |a _ b:X _ c _ d:Y _|,
/// even though those selectors may not appear on their own in any stylesheet.
/// This allows us to quickly scan through the dependency sites of all style
/// rules and determine the maximum effect that a given state or attribute
/// change may have on the style of elements in the document.
#[derive(Debug)]
#[cfg_attr(feature = "servo", derive(HeapSizeOf))]
struct Dependency {
#[cfg_attr(feature = "servo", ignore_heap_size_of = "Arc")]
selector: Arc<ComplexSelector<SelectorImpl>>,
hint: RestyleHint,
sensitivities: Sensitivities,
}
/// A set of dependencies for a given stylist.
///
/// Note that there are measurable perf wins from storing them separately
/// depending on what kind of change they affect, and its also not a big deal to
/// do it, since the dependencies are per-document.
#[derive(Debug)]
#[cfg_attr(feature = "servo", derive(HeapSizeOf))]
pub struct DependencySet {
/// Dependencies only affected by state.
state_deps: Vec<Dependency>,
/// Dependencies only affected by attributes.
attr_deps: Vec<Dependency>,
/// Dependencies affected by both.
common_deps: Vec<Dependency>,
}
impl DependencySet {
fn add_dependency(&mut self, dep: Dependency) {
let affects_attrs = dep.sensitivities.attrs;
let affects_states = !dep.sensitivities.states.is_empty();
if affects_attrs && affects_states {
self.common_deps.push(dep)
} else if affects_attrs {
self.attr_deps.push(dep)
} else {
self.state_deps.push(dep)
}
}
pub fn new() -> Self {
DependencySet {
state_deps: vec![],
attr_deps: vec![],
common_deps: vec![],
}
}
pub fn len(&self) -> usize {
self.common_deps.len() + self.attr_deps.len() + self.state_deps.len()
}
pub fn note_selector(&mut self, selector: &Arc<ComplexSelector<SelectorImpl>>) {
let mut cur = selector;
let mut combinator: Option<Combinator> = None;
loop {
let mut sensitivities = Sensitivities::new();
for s in &cur.compound_selector {
sensitivities.states.insert(selector_to_state(s));
if !sensitivities.attrs {
sensitivities.attrs = is_attr_selector(s);
}
}
if !sensitivities.is_empty() {
self.add_dependency(Dependency {
selector: cur.clone(),
hint: combinator_to_restyle_hint(combinator),
sensitivities: sensitivities,
});
}
cur = match cur.next {
Some((ref sel, comb)) => {
combinator = Some(comb);
sel
}
None => break,
}
}
}
pub fn clear(&mut self) {
self.common_deps.clear();
self.attr_deps.clear();
self.state_deps.clear();
}
pub fn compute_hint<E>(&self, el: &E,
snapshot: &Snapshot,
current_state: ElementState)
-> RestyleHint
where E: ElementExt + Clone
{
debug!("About to calculate restyle hint for element. Deps: {}",
self.len());
let state_changes = snapshot.state()
.map_or_else(ElementState::empty, |old_state| current_state ^ old_state);
let attrs_changed = snapshot.has_attrs();
if state_changes.is_empty() && !attrs_changed {
return RestyleHint::empty();
}
let mut hint = RestyleHint::empty();
let snapshot = ElementWrapper::new_with_snapshot(el.clone(), snapshot);
Self::compute_partial_hint(&self.common_deps, el, &snapshot,
&state_changes, attrs_changed, &mut hint);
if !state_changes.is_empty() {
Self::compute_partial_hint(&self.state_deps, el, &snapshot,
&state_changes, attrs_changed, &mut hint);
}
if attrs_changed {
Self::compute_partial_hint(&self.attr_deps, el, &snapshot,
&state_changes, attrs_changed, &mut hint);
}
hint
}
fn compute_partial_hint<E>(deps: &[Dependency],
element: &E,
snapshot: &ElementWrapper<E>,
state_changes: &ElementState,
attrs_changed: bool,
hint: &mut RestyleHint)
where E: ElementExt
{
if hint.is_all() {
return;
}
for dep in deps {
debug_assert!((!state_changes.is_empty() && !dep.sensitivities.states.is_empty()) ||
(attrs_changed && dep.sensitivities.attrs),
"Testing a known ineffective dependency?");
if (attrs_changed || state_changes.intersects(dep.sensitivities.states)) && !hint.intersects(dep.hint) {
let matched_then =
matches_complex_selector(&dep.selector, snapshot, None,
&mut StyleRelations::empty(),
MatchingReason::Other);
let matches_now =
matches_complex_selector(&dep.selector, element, None,
&mut StyleRelations::empty(),
MatchingReason::Other);
if matched_then != matches_now {
hint.insert(dep.hint);
}
if hint.is_all() {
break;
}
}
}
}
}
Reference in New Issue View Git Blame Copy Permalink