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// Copyright 2015 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "third_party/blink/renderer/core/dom/nth_index_cache.h"
#include "third_party/blink/renderer/core/dom/document.h"
#include "third_party/blink/renderer/core/dom/element_traversal.h"
namespace blink {
NthIndexCache::NthIndexCache(Document& document)
: document_(&document)
#if DCHECK_IS_ON()
,
dom_tree_version_(document.DomTreeVersion())
#endif
{
document.SetNthIndexCache(this);
}
NthIndexCache::~NthIndexCache() {
#if DCHECK_IS_ON()
DCHECK_EQ(dom_tree_version_, document_->DomTreeVersion());
#endif
document_->SetNthIndexCache(nullptr);
}
namespace {
// Generating the cached nth-index counts when the number of children
// exceeds this count. This number is picked based on testing
// querySelectorAll for :nth-child(3n+2) and :nth-of-type(3n+2) on an
// increasing number of children.
const unsigned kCachedSiblingCountLimit = 32;
unsigned UncachedNthChildIndex(Element& element) {
int index = 1;
for (const Element* sibling = ElementTraversal::PreviousSibling(element);
sibling; sibling = ElementTraversal::PreviousSibling(*sibling))
index++;
return index;
}
unsigned UncachedNthLastChildIndex(Element& element) {
int index = 1;
for (const Element* sibling = ElementTraversal::NextSibling(element); sibling;
sibling = ElementTraversal::NextSibling(*sibling))
++index;
return index;
}
unsigned UncachedNthOfTypeIndex(Element& element, unsigned& sibling_count) {
int index = 1;
const QualifiedName& tag = element.TagQName();
for (const Element* sibling = ElementTraversal::PreviousSibling(element);
sibling; sibling = ElementTraversal::PreviousSibling(*sibling)) {
if (sibling->TagQName() == tag)
++index;
++sibling_count;
}
return index;
}
unsigned UncachedNthLastOfTypeIndex(Element& element, unsigned& sibling_count) {
int index = 1;
const QualifiedName& tag = element.TagQName();
for (const Element* sibling = ElementTraversal::NextSibling(element); sibling;
sibling = ElementTraversal::NextSibling(*sibling)) {
if (sibling->TagQName() == tag)
++index;
++sibling_count;
}
return index;
}
} // namespace
unsigned NthIndexCache::NthChildIndex(Element& element) {
if (element.IsPseudoElement() || !element.parentNode())
return 1;
NthIndexCache* nth_index_cache = element.GetDocument().GetNthIndexCache();
NthIndexData* nth_index_data = nullptr;
if (nth_index_cache && nth_index_cache->parent_map_)
nth_index_data = nth_index_cache->parent_map_->at(element.parentNode());
if (nth_index_data)
return nth_index_data->NthIndex(element);
unsigned index = UncachedNthChildIndex(element);
if (nth_index_cache && index > kCachedSiblingCountLimit)
nth_index_cache->CacheNthIndexDataForParent(element);
return index;
}
unsigned NthIndexCache::NthLastChildIndex(Element& element) {
if (element.IsPseudoElement() && !element.parentNode())
return 1;
NthIndexCache* nth_index_cache = element.GetDocument().GetNthIndexCache();
NthIndexData* nth_index_data = nullptr;
if (nth_index_cache && nth_index_cache->parent_map_)
nth_index_data = nth_index_cache->parent_map_->at(element.parentNode());
if (nth_index_data)
return nth_index_data->NthLastIndex(element);
unsigned index = UncachedNthLastChildIndex(element);
if (nth_index_cache && index > kCachedSiblingCountLimit)
nth_index_cache->CacheNthIndexDataForParent(element);
return index;
}
NthIndexData* NthIndexCache::NthTypeIndexDataForParent(Element& element) const {
DCHECK(element.parentNode());
if (!parent_map_for_type_)
return nullptr;
if (const IndexByType* map = parent_map_for_type_->at(element.parentNode()))
return map->at(element.tagName());
return nullptr;
}
unsigned NthIndexCache::NthOfTypeIndex(Element& element) {
if (element.IsPseudoElement() || !element.parentNode())
return 1;
NthIndexCache* nth_index_cache = element.GetDocument().GetNthIndexCache();
if (nth_index_cache) {
if (NthIndexData* nth_index_data =
nth_index_cache->NthTypeIndexDataForParent(element))
return nth_index_data->NthOfTypeIndex(element);
}
unsigned sibling_count = 0;
unsigned index = UncachedNthOfTypeIndex(element, sibling_count);
if (nth_index_cache && sibling_count > kCachedSiblingCountLimit)
nth_index_cache->CacheNthOfTypeIndexDataForParent(element);
return index;
}
unsigned NthIndexCache::NthLastOfTypeIndex(Element& element) {
if (element.IsPseudoElement() || !element.parentNode())
return 1;
NthIndexCache* nth_index_cache = element.GetDocument().GetNthIndexCache();
if (nth_index_cache) {
if (NthIndexData* nth_index_data =
nth_index_cache->NthTypeIndexDataForParent(element))
return nth_index_data->NthLastOfTypeIndex(element);
}
unsigned sibling_count = 0;
unsigned index = UncachedNthLastOfTypeIndex(element, sibling_count);
if (nth_index_cache && sibling_count > kCachedSiblingCountLimit)
nth_index_cache->CacheNthOfTypeIndexDataForParent(element);
return index;
}
void NthIndexCache::CacheNthIndexDataForParent(Element& element) {
DCHECK(element.parentNode());
if (!parent_map_)
parent_map_ = MakeGarbageCollected<ParentMap>();
ParentMap::AddResult add_result =
parent_map_->insert(element.parentNode(), nullptr);
DCHECK(add_result.is_new_entry);
add_result.stored_value->value =
MakeGarbageCollected<NthIndexData>(*element.parentNode());
}
NthIndexCache::IndexByType& NthIndexCache::EnsureTypeIndexMap(
ContainerNode& parent) {
if (!parent_map_for_type_)
parent_map_for_type_ = MakeGarbageCollected<ParentMapForType>();
ParentMapForType::AddResult add_result =
parent_map_for_type_->insert(&parent, nullptr);
if (add_result.is_new_entry)
add_result.stored_value->value = MakeGarbageCollected<IndexByType>();
DCHECK(add_result.stored_value->value);
return *add_result.stored_value->value;
}
void NthIndexCache::CacheNthOfTypeIndexDataForParent(Element& element) {
DCHECK(element.parentNode());
IndexByType::AddResult add_result = EnsureTypeIndexMap(*element.parentNode())
.insert(element.tagName(), nullptr);
DCHECK(add_result.is_new_entry);
add_result.stored_value->value = MakeGarbageCollected<NthIndexData>(
*element.parentNode(), element.TagQName());
}
unsigned NthIndexData::NthIndex(Element& element) const {
DCHECK(!element.IsPseudoElement());
unsigned index = 0;
for (Element *sibling = &element; sibling;
sibling = ElementTraversal::PreviousSibling(*sibling), index++) {
auto it = element_index_map_.find(sibling);
if (it != element_index_map_.end())
return it->value + index;
}
return index;
}
unsigned NthIndexData::NthOfTypeIndex(Element& element) const {
DCHECK(!element.IsPseudoElement());
unsigned index = 0;
for (Element *sibling = &element; sibling;
sibling = ElementTraversal::PreviousSibling(
*sibling, HasTagName(element.TagQName())),
index++) {
auto it = element_index_map_.find(sibling);
if (it != element_index_map_.end())
return it->value + index;
}
return index;
}
unsigned NthIndexData::NthLastIndex(Element& element) const {
return count_ - NthIndex(element) + 1;
}
unsigned NthIndexData::NthLastOfTypeIndex(Element& element) const {
return count_ - NthOfTypeIndex(element) + 1;
}
NthIndexData::NthIndexData(ContainerNode& parent) {
// The frequency at which we cache the nth-index for a set of siblings. A
// spread value of 3 means every third Element will have its nth-index cached.
// Using a spread value > 1 is done to save memory. Looking up the nth-index
// will still be done in constant time in terms of sibling count, at most
// 'spread' elements will be traversed.
const unsigned kSpread = 3;
unsigned count = 0;
for (Element* sibling = ElementTraversal::FirstChild(parent); sibling;
sibling = ElementTraversal::NextSibling(*sibling)) {
if (!(++count % kSpread))
element_index_map_.insert(sibling, count);
}
DCHECK(count);
count_ = count;
}
NthIndexData::NthIndexData(ContainerNode& parent, const QualifiedName& type) {
// The frequency at which we cache the nth-index of type for a set of
// siblings. A spread value of 3 means every third Element of its type will
// have its nth-index cached. Using a spread value > 1 is done to save
// memory. Looking up the nth-index of its type will still be done in less
// time, as most number of elements traversed will be equal to find 'spread'
// elements in the sibling set.
const unsigned kSpread = 3;
unsigned count = 0;
for (Element* sibling =
ElementTraversal::FirstChild(parent, HasTagName(type));
sibling;
sibling = ElementTraversal::NextSibling(*sibling, HasTagName(type))) {
if (!(++count % kSpread))
element_index_map_.insert(sibling, count);
}
DCHECK(count);
count_ = count;
}
void NthIndexData::Trace(Visitor* visitor) {
visitor->Trace(element_index_map_);
}
} // namespace blink
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