| /** |
| * Copyright (C) 2004 Allan Sandfeld Jensen (kde@carewolf.com) |
| * Copyright (C) 2006, 2007 Apple Inc. All rights reserved. |
| * |
| * This library is free software; you can redistribute it and/or |
| * modify it under the terms of the GNU Library General Public |
| * License as published by the Free Software Foundation; either |
| * version 2 of the License, or (at your option) any later version. |
| * |
| * This library is distributed in the hope that it will be useful, |
| * but WITHOUT ANY WARRANTY; without even the implied warranty of |
| * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU |
| * Library General Public License for more details. |
| * |
| * You should have received a copy of the GNU Library General Public License |
| * along with this library; see the file COPYING.LIB. If not, write to |
| * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, |
| * Boston, MA 02110-1301, USA. |
| * |
| */ |
| |
| #include "third_party/blink/renderer/core/layout/layout_counter.h" |
| |
| #include <memory> |
| |
| #include "base/memory/ptr_util.h" |
| #include "third_party/blink/renderer/core/dom/element.h" |
| #include "third_party/blink/renderer/core/dom/element_traversal.h" |
| #include "third_party/blink/renderer/core/dom/node_computed_style.h" |
| #include "third_party/blink/renderer/core/dom/pseudo_element.h" |
| #include "third_party/blink/renderer/core/html/html_olist_element.h" |
| #include "third_party/blink/renderer/core/html/list_item_ordinal.h" |
| #include "third_party/blink/renderer/core/layout/counter_node.h" |
| #include "third_party/blink/renderer/core/layout/layout_list_item.h" |
| #include "third_party/blink/renderer/core/layout/layout_view.h" |
| #include "third_party/blink/renderer/core/layout/list_marker_text.h" |
| #include "third_party/blink/renderer/core/style/computed_style.h" |
| #include "third_party/blink/renderer/platform/wtf/std_lib_extras.h" |
| |
| #if DCHECK_IS_ON() |
| #include <stdio.h> |
| #endif |
| |
| namespace blink { |
| |
| typedef HashMap<const LayoutObject*, std::unique_ptr<CounterMap>> CounterMaps; |
| |
| namespace { |
| |
| CounterNode* MakeCounterNodeIfNeeded(LayoutObject&, |
| const AtomicString& identifier, |
| bool always_create_counter); |
| |
| // See class definition as to why we have this map. |
| CounterMaps& GetCounterMaps() { |
| DEFINE_STATIC_LOCAL(CounterMaps, static_counter_maps, ()); |
| return static_counter_maps; |
| } |
| |
| Element* AncestorStyleContainmentObject(const Element& element) { |
| for (Element* ancestor = FlatTreeTraversal::ParentElement(element); ancestor; |
| ancestor = FlatTreeTraversal::ParentElement(*ancestor)) { |
| if (const ComputedStyle* style = ancestor->GetComputedStyle()) { |
| if (style->ContainsStyle()) |
| return ancestor; |
| } |
| } |
| return nullptr; |
| } |
| |
| int ValueForText(CounterNode* node) { |
| return node->ActsAsReset() ? node->Value() : node->CountInParent(); |
| } |
| |
| // This function processes the DOM tree including pseudo elements as defined in |
| // CSS 2.1. This method will always return either a previous element within the |
| // same contain: style scope or nullptr. |
| Element* PreviousInPreOrderRespectingContainment(const Element& element) { |
| Element* previous = ElementTraversal::PreviousIncludingPseudo(element); |
| Element* style_contain_ancestor = AncestorStyleContainmentObject(element); |
| |
| while (true) { |
| // Find the candidate previous element. |
| while (previous && !previous->GetLayoutObject() && |
| !previous->HasDisplayContentsStyle()) |
| previous = ElementTraversal::PreviousIncludingPseudo(*previous); |
| if (!previous) |
| return nullptr; |
| Element* previous_style_contain_ancestor = |
| AncestorStyleContainmentObject(*previous); |
| // If the candidate's containment ancestor is the same as elements, then |
| // that's a valid candidate. |
| if (previous_style_contain_ancestor == style_contain_ancestor) |
| return previous; |
| |
| // Otherwise, if previous does not have a containment ancestor, it means |
| // that we have already escaped `element`'s containment ancestor, so return |
| // nullptr. |
| if (!previous_style_contain_ancestor) |
| return nullptr; |
| |
| // If, however, the candidate does have a containment ancestor, it could be |
| // that we entered a new sub-containment. Try again starting from the |
| // contain ancestor. |
| previous = previous_style_contain_ancestor; |
| } |
| } |
| |
| // This function processes the DOM including pseudo elements as defined in |
| // CSS 2.1. This method avoids crossing contain: style boundaries. |
| Element* PreviousSiblingOrParentRespectingContainment(const Element& element) { |
| Element* previous = ElementTraversal::PseudoAwarePreviousSibling(element); |
| // Skip display:none elements. |
| while (previous && !previous->GetLayoutObject() && |
| !previous->HasDisplayContentsStyle()) |
| previous = ElementTraversal::PseudoAwarePreviousSibling(*previous); |
| if (previous) |
| return previous; |
| previous = element.parentElement(); |
| if (previous) { |
| if (const ComputedStyle* style = previous->GetComputedStyle()) { |
| if (style->ContainsStyle()) |
| return nullptr; |
| } |
| } |
| return previous; |
| } |
| |
| inline bool AreElementsSiblings(const Element& first, const Element& second) { |
| return first.parentElement() == second.parentElement(); |
| } |
| |
| // This function processes the the DOM tree including pseudo elements as defined |
| // in CSS 2.1. |
| LayoutObject* NextInPreOrder(const LayoutObject& object, |
| const Element* stay_within, |
| bool skip_descendants = false) { |
| auto* self = To<Element>(object.GetNode()); |
| DCHECK(self); |
| Element* next = |
| skip_descendants |
| ? ElementTraversal::NextIncludingPseudoSkippingChildren(*self, |
| stay_within) |
| : ElementTraversal::NextIncludingPseudo(*self, stay_within); |
| while (next && !next->GetLayoutObject()) |
| next = skip_descendants |
| ? ElementTraversal::NextIncludingPseudoSkippingChildren( |
| *next, stay_within) |
| : ElementTraversal::NextIncludingPseudo(*next, stay_within); |
| return next ? next->GetLayoutObject() : nullptr; |
| } |
| |
| bool PlanCounter(LayoutObject& object, |
| const AtomicString& identifier, |
| unsigned& type_mask, |
| int& value) { |
| // Real text nodes don't have their own style so they can't have counters. |
| // We can't even look at their styles or we'll see extra resets and |
| // increments! |
| if (object.IsText() && !object.IsBR()) |
| return false; |
| Node* generating_node = object.GeneratingNode(); |
| // We must have a generating node or else we cannot have a counter. |
| if (!generating_node) |
| return false; |
| const ComputedStyle& style = object.StyleRef(); |
| |
| switch (style.StyleType()) { |
| case kPseudoIdNone: |
| // Sometimes nodes have more than one layout object. Only the first one |
| // gets the counter. See web_tests/http/tests/css/counter-crash.html |
| if (generating_node->GetLayoutObject() != &object) |
| return false; |
| break; |
| case kPseudoIdBefore: |
| case kPseudoIdAfter: |
| case kPseudoIdMarker: |
| break; |
| default: |
| return false; // Counters are forbidden from all other pseudo elements. |
| } |
| |
| type_mask = 0; |
| const CounterDirectives directives = style.GetCounterDirectives(identifier); |
| if (directives.IsDefined()) { |
| value = directives.CombinedValue(); |
| type_mask |= directives.IsIncrement() ? CounterNode::kIncrementType : 0; |
| type_mask |= directives.IsReset() ? CounterNode::kResetType : 0; |
| type_mask |= directives.IsSet() ? CounterNode::kSetType : 0; |
| return true; |
| } |
| |
| if (identifier == "list-item") { |
| if (Node* e = object.GetNode()) { |
| if (ListItemOrdinal* ordinal = ListItemOrdinal::Get(*e)) { |
| if (const auto& explicit_value = ordinal->ExplicitValue()) { |
| value = explicit_value.value(); |
| type_mask = CounterNode::kResetType; |
| return true; |
| } |
| value = ListItemOrdinal::IsInReversedOrderedList(*e) ? -1 : 1; |
| type_mask = CounterNode::kIncrementType; |
| return true; |
| } |
| if (auto* olist = DynamicTo<HTMLOListElement>(*e)) { |
| value = |
| olist->StartConsideringItemCount() + (olist->IsReversed() ? 1 : -1); |
| type_mask = CounterNode::kResetType; |
| return true; |
| } |
| if (IsA<HTMLUListElement>(*e) || IsA<HTMLMenuElement>(*e) || |
| IsA<HTMLDirectoryElement>(*e)) { |
| value = 0; |
| type_mask = CounterNode::kResetType; |
| return true; |
| } |
| } |
| } |
| |
| return false; |
| } |
| |
| // - Finds the insertion point for the counter described by counter_owner, |
| // IsReset and identifier in the CounterNode tree for identifier and sets |
| // parent and previous_sibling accordingly. |
| // - The function returns true if the counter whose insertion point is searched |
| // is NOT the root of the tree. |
| // - The root of the tree is a counter reference that is not in the scope of any |
| // other counter with the same identifier. |
| // - All the counter references with the same identifier as this one that are in |
| // children or subsequent siblings of the layout object that owns the root of |
| // the tree form the rest of of the nodes of the tree. |
| // - The root of the tree is always a reset type reference. |
| // - A subtree rooted at any reset node in the tree is equivalent to all counter |
| // references that are in the scope of the counter or nested counter defined |
| // by that reset node. |
| // - Non-reset CounterNodes cannot have descendants. |
| bool FindPlaceForCounter(LayoutObject& counter_owner, |
| const AtomicString& identifier, |
| bool is_reset, |
| scoped_refptr<CounterNode>& parent, |
| scoped_refptr<CounterNode>& previous_sibling) { |
| // We cannot stop searching for counters with the same identifier before we |
| // also check this layout object, because it may affect the positioning in the |
| // tree of our counter. |
| auto* counter_owner_element = To<Element>(counter_owner.GetNode()); |
| Element* search_end_element = |
| PreviousSiblingOrParentRespectingContainment(*counter_owner_element); |
| Element* current_element = |
| PreviousInPreOrderRespectingContainment(*counter_owner_element); |
| previous_sibling = nullptr; |
| scoped_refptr<CounterNode> previous_sibling_protector = nullptr; |
| while (current_element) { |
| CounterNode* current_counter = nullptr; |
| if (LayoutObject* current_layout_object = |
| current_element->GetLayoutObject()) { |
| current_counter = |
| MakeCounterNodeIfNeeded(*current_layout_object, identifier, false); |
| } |
| if (search_end_element == current_element) { |
| // We may be at the end of our search. |
| if (current_counter) { |
| // We have a suitable counter on the search_end_element. |
| if (previous_sibling_protector) { |
| // But we already found another counter that we come after. |
| if (current_counter->ActsAsReset()) { |
| // We found a reset counter that is on a layout object that is a |
| // sibling of ours or a parent. |
| if (is_reset && |
| AreElementsSiblings(*current_element, *counter_owner_element)) { |
| // We are also a reset counter and the previous reset was on a |
| // sibling layout object hence we are the next sibling of that |
| // counter if that reset is not a root or we are a root node if |
| // that reset is a root. |
| parent = current_counter->Parent(); |
| previous_sibling = parent ? current_counter : nullptr; |
| return parent.get(); |
| } |
| // We are not a reset node or the previous reset must be on an |
| // ancestor of our owner layout object hence we must be a child of |
| // that reset counter. |
| parent = current_counter; |
| // In some cases layout objects can be reparented (ex. nodes inside |
| // a table but not in a column or row). In these cases the |
| // identified previous_sibling will be invalid as its parent is |
| // different from our identified parent. |
| if (previous_sibling_protector->Parent() != current_counter) |
| previous_sibling_protector = nullptr; |
| |
| previous_sibling = previous_sibling_protector.get(); |
| return true; |
| } |
| // CurrentCounter, the counter at the EndSearchLayoutObject, is not |
| // reset. |
| if (!is_reset || |
| !AreElementsSiblings(*current_element, *counter_owner_element)) { |
| // If the node we are placing is not reset or we have found a |
| // counter that is attached to an ancestor of the placed counter's |
| // owner layout object we know we are a sibling of that node. |
| if (current_counter->Parent() != |
| previous_sibling_protector->Parent()) |
| return false; |
| |
| parent = current_counter->Parent(); |
| previous_sibling = previous_sibling_protector.get(); |
| return true; |
| } |
| } else { |
| // We are at the potential end of the search, but we had no previous |
| // sibling candidate. In this case we follow pretty much the same |
| // logic as above but no ASSERTs about previous_sibling, and when we |
| // are a sibling of the end counter we must set previous_sibling to |
| // current_counter. |
| if (current_counter->ActsAsReset()) { |
| if (is_reset && |
| AreElementsSiblings(*current_element, *counter_owner_element)) { |
| parent = current_counter->Parent(); |
| previous_sibling = current_counter; |
| return parent.get(); |
| } |
| parent = current_counter; |
| previous_sibling = previous_sibling_protector.get(); |
| return true; |
| } |
| if (!is_reset || |
| !AreElementsSiblings(*current_element, *counter_owner_element)) { |
| parent = current_counter->Parent(); |
| previous_sibling = current_counter; |
| return true; |
| } |
| previous_sibling_protector = current_counter; |
| } |
| } |
| // We come here if the previous sibling or parent of our owner |
| // layout_object had no good counter, or we are a reset node and the |
| // counter on the previous sibling of our owner layout_object was not a |
| // reset counter. Set a new goal for the end of the search. |
| search_end_element = |
| PreviousSiblingOrParentRespectingContainment(*current_element); |
| } else { |
| // We are searching descendants of a previous sibling of the layout object |
| // that the |
| // counter being placed is attached to. |
| if (current_counter) { |
| // We found a suitable counter. |
| if (previous_sibling_protector) { |
| // Since we had a suitable previous counter before, we should only |
| // consider this one as our previous_sibling if it is a reset counter |
| // and hence the current previous_sibling is its child. |
| if (current_counter->ActsAsReset()) { |
| previous_sibling_protector = current_counter; |
| // We are no longer interested in previous siblings of the |
| // current_element or their children as counters they may have |
| // attached cannot be the previous sibling of the counter we are |
| // placing. |
| current_element = current_element->parentElement(); |
| continue; |
| } |
| } else { |
| previous_sibling_protector = current_counter; |
| } |
| current_element = |
| PreviousSiblingOrParentRespectingContainment(*current_element); |
| continue; |
| } |
| } |
| // This function is designed so that the same test is not done twice in an |
| // iteration, except for this one which may be done twice in some cases. |
| // Rearranging the decision points though, to accommodate this performance |
| // improvement would create more code duplication than is worthwhile in my |
| // opinion and may further impede the readability of this already complex |
| // algorithm. |
| if (previous_sibling_protector) { |
| current_element = |
| PreviousSiblingOrParentRespectingContainment(*current_element); |
| } else { |
| current_element = |
| PreviousInPreOrderRespectingContainment(*current_element); |
| } |
| } |
| return false; |
| } |
| |
| inline Element* ParentElement(LayoutObject& object) { |
| return To<Element>(object.GetNode())->parentElement(); |
| } |
| |
| CounterNode* MakeCounterNodeIfNeeded(LayoutObject& object, |
| const AtomicString& identifier, |
| bool always_create_counter) { |
| if (object.HasCounterNodeMap()) { |
| if (CounterMap* node_map = GetCounterMaps().at(&object)) { |
| if (CounterNode* node = node_map->at(identifier)) |
| return node; |
| } |
| } |
| |
| unsigned type_mask = 0; |
| int value = 0; |
| if (!PlanCounter(object, identifier, type_mask, value) && |
| !always_create_counter) |
| return nullptr; |
| |
| scoped_refptr<CounterNode> new_parent = nullptr; |
| scoped_refptr<CounterNode> new_previous_sibling = nullptr; |
| scoped_refptr<CounterNode> new_node = |
| CounterNode::Create(object, type_mask, value); |
| |
| if (type_mask & CounterNode::kResetType) { |
| // Find the place where we would've inserted the new node if it was a |
| // non-reset node. We have to move every non-reset sibling after the |
| // insertion point to a child of the new node. |
| scoped_refptr<CounterNode> old_parent = nullptr; |
| scoped_refptr<CounterNode> old_previous_sibling = nullptr; |
| if (FindPlaceForCounter(object, identifier, false, old_parent, |
| old_previous_sibling)) { |
| if (!object.IsDescendantOf(&old_parent->Owner())) { |
| CounterNode* first_node_to_move = |
| old_previous_sibling ? old_previous_sibling->NextSibling() |
| : old_parent->FirstChild(); |
| CounterNode::MoveNonResetSiblingsToChildOf(first_node_to_move, |
| *new_node, identifier); |
| } |
| } |
| } |
| |
| if (FindPlaceForCounter(object, identifier, |
| type_mask & CounterNode::kResetType, new_parent, |
| new_previous_sibling)) |
| new_parent->InsertAfter(new_node.get(), new_previous_sibling.get(), |
| identifier); |
| CounterMap* node_map; |
| if (object.HasCounterNodeMap()) { |
| node_map = GetCounterMaps().at(&object); |
| } else { |
| node_map = new CounterMap; |
| GetCounterMaps().Set(&object, base::WrapUnique(node_map)); |
| object.SetHasCounterNodeMap(true); |
| } |
| node_map->Set(identifier, new_node); |
| // If the new node has a parent, that means any descendant would have been |
| // updated by `CounterNode::MoveNonResetSiblingsToChildOf()` above, so we |
| // don't need to update descendants. Likewise, if the object has style |
| // containment, any descendant should not become parented across the boundary. |
| if (new_node->Parent() || object.ShouldApplyStyleContainment()) |
| return new_node.get(); |
| |
| // Checking if some nodes that were previously counter tree root nodes |
| // should become children of this node now. |
| CounterMaps& maps = GetCounterMaps(); |
| Element* stay_within = ParentElement(object); |
| bool skip_descendants; |
| for (LayoutObject* current_layout_object = |
| NextInPreOrder(object, stay_within); |
| current_layout_object; |
| current_layout_object = NextInPreOrder(*current_layout_object, |
| stay_within, skip_descendants)) { |
| // We'll update the current object and we might recurse into the |
| // descendants. However, if the object has style containment then we do not |
| // cross the boundary which begins right after the object. In other words we |
| // skip the descendants of this object. |
| skip_descendants = current_layout_object->ShouldApplyStyleContainment(); |
| if (!current_layout_object->HasCounterNodeMap()) |
| continue; |
| CounterNode* current_counter = |
| maps.at(current_layout_object)->at(identifier); |
| if (!current_counter) |
| continue; |
| // At this point we found a counter to reparent. So we don't need to descend |
| // into the layout tree further, since any further counters we find would be |
| // at most parented to `current_counter` we just found. |
| skip_descendants = true; |
| if (current_counter->Parent()) |
| continue; |
| if (stay_within == ParentElement(*current_layout_object) && |
| current_counter->HasResetType()) |
| break; |
| new_node->InsertAfter(current_counter, new_node->LastChild(), identifier); |
| } |
| return new_node.get(); |
| } |
| |
| } // namespace |
| |
| LayoutCounter::LayoutCounter(PseudoElement& pseudo, |
| const CounterContent& counter) |
| : LayoutText(nullptr, StringImpl::empty_), |
| counter_(counter), |
| counter_node_(nullptr), |
| next_for_same_counter_(nullptr) { |
| SetDocumentForAnonymous(&pseudo.GetDocument()); |
| View()->AddLayoutCounter(); |
| } |
| |
| LayoutCounter::~LayoutCounter() = default; |
| |
| void LayoutCounter::WillBeDestroyed() { |
| if (counter_node_) { |
| counter_node_->RemoveLayoutObject(this); |
| DCHECK(!counter_node_); |
| } |
| if (View()) |
| View()->RemoveLayoutCounter(); |
| LayoutText::WillBeDestroyed(); |
| } |
| |
| scoped_refptr<StringImpl> LayoutCounter::OriginalText() const { |
| // Child will be the base of our text that we report. First, we need to find |
| // an appropriate child. |
| CounterNode* child = nullptr; |
| |
| // Find a container on which to create the counter if one needs creating. |
| LayoutObject* container = Parent(); |
| bool should_create_counter = counter_.Separator().IsNull(); |
| // Optimization: the only reason we need a proper container is if we might not |
| // need to create a counter (in which case, we navigate container's |
| // ancestors), or if we don't have a counter_node_ (in which case we need to |
| // find the container to place the counter on). |
| if (!should_create_counter || !counter_node_) { |
| while (true) { |
| if (!container) |
| return nullptr; |
| if (!container->IsAnonymous() && !container->IsPseudoElement()) |
| return nullptr; // LayoutCounters are restricted to before, after and |
| // marker pseudo elements |
| PseudoId container_style = container->StyleRef().StyleType(); |
| if ((container_style == kPseudoIdBefore) || |
| (container_style == kPseudoIdAfter) || |
| (container_style == kPseudoIdMarker)) |
| break; |
| container = container->Parent(); |
| } |
| } |
| |
| // Now that we have a container, check if the counter directives are |
| // defined between us and the first style containment element, meaning that |
| // the counter would be created for our scope even if there is no content |
| // request. If not, and if the separator is not null, meaning the request was |
| // for something like counters(n, "."), then we first have to check our |
| // ancestors across the style containment boundary. If the ancestors have the |
| // value for our identifier, then we don't need a counter here and it is |
| // instead omitted. See counter-scoping-001.html WPT and crbug.com/882383#c11 |
| // for more context. |
| if (!should_create_counter) { |
| for (auto* scope_ancestor = container; scope_ancestor; |
| scope_ancestor = scope_ancestor->Parent()) { |
| auto& style = scope_ancestor->StyleRef(); |
| if (style.ContainsStyle()) |
| break; |
| const CounterDirectives directives = |
| style.GetCounterDirectives(counter_.Identifier()); |
| if (directives.IsDefined()) { |
| should_create_counter = true; |
| break; |
| } |
| } |
| } |
| |
| if (!should_create_counter) { |
| // If we have an ancestor across the the containment boundary, then use it |
| // as the child, without needing to create a counter on `this`. If we don't |
| // have such an ancestor, we need to create a `counter_node_` on `this`. |
| if (auto* node = CounterNode::AncestorNodeAcrossStyleContainment( |
| *this, counter_.Identifier())) { |
| child = node; |
| } else { |
| should_create_counter = true; |
| } |
| } |
| |
| if (should_create_counter) { |
| if (!counter_node_) { |
| MakeCounterNodeIfNeeded(*container, counter_.Identifier(), true) |
| ->AddLayoutObject(const_cast<LayoutCounter*>(this)); |
| DCHECK(counter_node_); |
| } |
| child = counter_node_; |
| } |
| |
| // In all cases we should end up with a `child` which is the base of our |
| // navigation. |
| DCHECK(child); |
| |
| int value = ValueForText(child); |
| String text = list_marker_text::GetText(counter_.ListStyle(), value); |
| // If the separator exists, we need to append all of the parent values as well, |
| // including the ones that cross the style containment boundary. |
| if (!counter_.Separator().IsNull()) { |
| if (!child->ActsAsReset()) |
| child = child->ParentCrossingStyleContainment(counter_.Identifier()); |
| bool next_result_uses_parent_value = !child->Parent(); |
| while (CounterNode* parent = |
| child->ParentCrossingStyleContainment(counter_.Identifier())) { |
| text = list_marker_text::GetText(counter_.ListStyle(), |
| next_result_uses_parent_value |
| ? ValueForText(parent) |
| : child->CountInParent()) + |
| counter_.Separator() + text; |
| child = parent; |
| next_result_uses_parent_value = !child->Parent(); |
| } |
| } |
| |
| return text.ReleaseImpl(); |
| } |
| |
| void LayoutCounter::UpdateCounter() { |
| SetTextIfNeeded(OriginalText()); |
| } |
| |
| void LayoutCounter::Invalidate() { |
| counter_node_->RemoveLayoutObject(this); |
| DCHECK(!counter_node_); |
| if (DocumentBeingDestroyed()) |
| return; |
| SetNeedsLayoutAndIntrinsicWidthsRecalcAndFullPaintInvalidation( |
| layout_invalidation_reason::kCountersChanged); |
| } |
| |
| static void DestroyCounterNodeWithoutMapRemoval(const AtomicString& identifier, |
| CounterNode* node) { |
| CounterNode* previous; |
| for (scoped_refptr<CounterNode> child = node->LastDescendant(); |
| child && child != node; child = previous) { |
| previous = child->PreviousInPreOrder(); |
| child->Parent()->RemoveChild(child.get()); |
| DCHECK(GetCounterMaps().at(&child->Owner())->at(identifier) == child); |
| GetCounterMaps().at(&child->Owner())->erase(identifier); |
| } |
| if (CounterNode* parent = node->Parent()) |
| parent->RemoveChild(node); |
| } |
| |
| void LayoutCounter::DestroyCounterNodes(LayoutObject& owner) { |
| CounterMaps& maps = GetCounterMaps(); |
| CounterMaps::iterator maps_iterator = maps.find(&owner); |
| if (maps_iterator == maps.end()) |
| return; |
| CounterMap* map = maps_iterator->value.get(); |
| CounterMap::const_iterator end = map->end(); |
| for (CounterMap::const_iterator it = map->begin(); it != end; ++it) { |
| DestroyCounterNodeWithoutMapRemoval(it->key, it->value.get()); |
| } |
| maps.erase(maps_iterator); |
| owner.SetHasCounterNodeMap(false); |
| if (owner.View()) |
| owner.View()->SetNeedsCounterUpdate(); |
| } |
| |
| void LayoutCounter::DestroyCounterNode(LayoutObject& owner, |
| const AtomicString& identifier) { |
| CounterMap* map = GetCounterMaps().at(&owner); |
| if (!map) |
| return; |
| CounterMap::iterator map_iterator = map->find(identifier); |
| if (map_iterator == map->end()) |
| return; |
| DestroyCounterNodeWithoutMapRemoval(identifier, map_iterator->value.get()); |
| map->erase(map_iterator); |
| // We do not delete "map" here even if empty because we expect to reuse |
| // it soon. In order for a layout object to lose all its counters permanently, |
| // a style change for the layout object involving removal of all counter |
| // directives must occur, in which case, LayoutCounter::DestroyCounterNodes() |
| // must be called. |
| // The destruction of the LayoutObject (possibly caused by the removal of its |
| // associated DOM node) is the other case that leads to the permanent |
| // destruction of all counters attached to a LayoutObject. In this case |
| // LayoutCounter::DestroyCounterNodes() must be and is now called, too. |
| // LayoutCounter::DestroyCounterNodes() handles destruction of the counter |
| // map associated with a layout object, so there is no risk in leaking the |
| // map. |
| } |
| |
| void LayoutCounter::LayoutObjectSubtreeWillBeDetached( |
| LayoutObject* layout_object) { |
| DCHECK(layout_object->View()); |
| // View should never be non-zero. crbug.com/546939 |
| if (!layout_object->View() || !layout_object->View()->HasLayoutCounters()) |
| return; |
| |
| LayoutObject* current_layout_object = layout_object->LastLeafChild(); |
| if (!current_layout_object) |
| current_layout_object = layout_object; |
| while (true) { |
| DestroyCounterNodes(*current_layout_object); |
| if (current_layout_object == layout_object) |
| break; |
| current_layout_object = current_layout_object->PreviousInPreOrder(); |
| } |
| } |
| |
| static void UpdateCounters(LayoutObject& layout_object) { |
| DCHECK(layout_object.Style()); |
| const CounterDirectiveMap* directive_map = |
| layout_object.StyleRef().GetCounterDirectives(); |
| if (!directive_map) |
| return; |
| CounterDirectiveMap::const_iterator end = directive_map->end(); |
| if (!layout_object.HasCounterNodeMap()) { |
| for (CounterDirectiveMap::const_iterator it = directive_map->begin(); |
| it != end; ++it) |
| MakeCounterNodeIfNeeded(layout_object, it->key, false); |
| return; |
| } |
| CounterMap* counter_map = GetCounterMaps().at(&layout_object); |
| DCHECK(counter_map); |
| for (CounterDirectiveMap::const_iterator it = directive_map->begin(); |
| it != end; ++it) { |
| scoped_refptr<CounterNode> node = counter_map->at(it->key); |
| if (!node) { |
| MakeCounterNodeIfNeeded(layout_object, it->key, false); |
| continue; |
| } |
| scoped_refptr<CounterNode> new_parent = nullptr; |
| scoped_refptr<CounterNode> new_previous_sibling = nullptr; |
| |
| FindPlaceForCounter(layout_object, it->key, node->HasResetType(), |
| new_parent, new_previous_sibling); |
| if (node != counter_map->at(it->key)) |
| continue; |
| CounterNode* parent = node->Parent(); |
| if (new_parent == parent && new_previous_sibling == node->PreviousSibling()) |
| continue; |
| if (parent) |
| parent->RemoveChild(node.get()); |
| if (new_parent) |
| new_parent->InsertAfter(node.get(), new_previous_sibling.get(), it->key); |
| } |
| } |
| |
| void LayoutCounter::LayoutObjectSubtreeAttached(LayoutObject* layout_object) { |
| DCHECK(layout_object->View()); |
| // Only update counters if we have LayoutCounter which is created when we have |
| // a content: field with a counter requirement. |
| if (!layout_object->View()->HasLayoutCounters()) |
| return; |
| Node* node = layout_object->GetNode(); |
| if (node) |
| node = node->parentNode(); |
| else |
| node = layout_object->GeneratingNode(); |
| if (node && node->NeedsReattachLayoutTree()) |
| return; // No need to update if the parent is not attached yet |
| |
| // Update the descendants. |
| for (LayoutObject* descendant = layout_object; descendant; |
| descendant = descendant->NextInPreOrder(layout_object)) |
| UpdateCounters(*descendant); |
| |
| bool crossed_boundary = false; |
| // Since we skipped counter updates if there were no counters, we might need |
| // to update parent counters that lie beyond the style containment boundary. |
| for (LayoutObject* parent = layout_object->Parent(); parent; |
| parent = parent->Parent()) { |
| crossed_boundary |= parent->ShouldApplyStyleContainment(); |
| if (crossed_boundary) |
| UpdateCounters(*parent); |
| } |
| } |
| |
| void LayoutCounter::LayoutObjectStyleChanged(LayoutObject& layout_object, |
| const ComputedStyle* old_style, |
| const ComputedStyle& new_style) { |
| Node* node = layout_object.GeneratingNode(); |
| if (!node || node->NeedsReattachLayoutTree()) |
| return; // cannot have generated content or if it can have, it will be |
| // handled during attaching |
| const CounterDirectiveMap* old_counter_directives = |
| old_style ? old_style->GetCounterDirectives() : nullptr; |
| const CounterDirectiveMap* new_counter_directives = |
| new_style.GetCounterDirectives(); |
| if (old_counter_directives) { |
| if (new_counter_directives) { |
| CounterDirectiveMap::const_iterator new_map_end = |
| new_counter_directives->end(); |
| CounterDirectiveMap::const_iterator old_map_end = |
| old_counter_directives->end(); |
| for (CounterDirectiveMap::const_iterator it = |
| new_counter_directives->begin(); |
| it != new_map_end; ++it) { |
| CounterDirectiveMap::const_iterator old_map_it = |
| old_counter_directives->find(it->key); |
| if (old_map_it != old_map_end) { |
| if (old_map_it->value == it->value) |
| continue; |
| LayoutCounter::DestroyCounterNode(layout_object, it->key); |
| } |
| // We must create this node here, because the changed node may be a node |
| // with no display such as as those created by the increment or reset |
| // directives and the re-layout that will happen will not catch the |
| // change if the node had no children. |
| MakeCounterNodeIfNeeded(layout_object, it->key, false); |
| } |
| // Destroying old counters that do not exist in the new counterDirective |
| // map. |
| for (CounterDirectiveMap::const_iterator it = |
| old_counter_directives->begin(); |
| it != old_map_end; ++it) { |
| if (!new_counter_directives->Contains(it->key)) |
| LayoutCounter::DestroyCounterNode(layout_object, it->key); |
| } |
| } else { |
| if (layout_object.HasCounterNodeMap()) |
| LayoutCounter::DestroyCounterNodes(layout_object); |
| } |
| } else if (new_counter_directives) { |
| if (layout_object.HasCounterNodeMap()) |
| LayoutCounter::DestroyCounterNodes(layout_object); |
| CounterDirectiveMap::const_iterator new_map_end = |
| new_counter_directives->end(); |
| for (CounterDirectiveMap::const_iterator it = |
| new_counter_directives->begin(); |
| it != new_map_end; ++it) { |
| // We must create this node here, because the added node may be a node |
| // with no display such as as those created by the increment or reset |
| // directives and the re-layout that will happen will not catch the change |
| // if the node had no children. |
| MakeCounterNodeIfNeeded(layout_object, it->key, false); |
| } |
| } |
| } |
| |
| // static |
| CounterMap* LayoutCounter::GetCounterMap(LayoutObject* object) { |
| if (object->HasCounterNodeMap()) |
| return GetCounterMaps().at(object); |
| return nullptr; |
| } |
| |
| } // namespace blink |
| |
| #if DCHECK_IS_ON() |
| |
| void showCounterLayoutTree(const blink::LayoutObject* layout_object, |
| const char* counter_name) { |
| if (!layout_object) |
| return; |
| const blink::LayoutObject* root = layout_object; |
| while (root->Parent()) |
| root = root->Parent(); |
| |
| AtomicString identifier(counter_name); |
| for (const blink::LayoutObject* current = root; current; |
| current = current->NextInPreOrder()) { |
| fprintf(stderr, "%c", (current == layout_object) ? '*' : ' '); |
| for (const blink::LayoutObject* parent = current; parent && parent != root; |
| parent = parent->Parent()) |
| fprintf(stderr, " "); |
| fprintf(stderr, "%p %s", current, current->DebugName().Utf8().c_str()); |
| auto* counter_node = |
| current->HasCounterNodeMap() && current |
| ? blink::GetCounterMaps().at(current)->at(identifier) |
| : nullptr; |
| if (counter_node) { |
| fprintf(stderr, " counter:%p parent:%p value:%d countInParent:%d\n", |
| counter_node, counter_node->Parent(), counter_node->Value(), |
| counter_node->CountInParent()); |
| } else { |
| fprintf(stderr, "\n"); |
| } |
| } |
| } |
| |
| #endif // DCHECK_IS_ON() |