Source/WebCore/dom/ComposedTreeIterator.h - WebKit - Git at Google

 /*
  * Copyright (C) 2015-2016 Apple Inc. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE INC. OR
  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
  * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
  * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #pragma once

 #include "ElementAndTextDescendantIterator.h"
 #include "HTMLSlotElement.h"
 #include "ShadowRoot.h"

 namespace WebCore {

 class HTMLSlotElement;

 class ComposedTreeIterator {
 public:
     ComposedTreeIterator();
     enum FirstChildTag { FirstChild };
     ComposedTreeIterator(ContainerNode& root, FirstChildTag);
     ComposedTreeIterator(ContainerNode& root, Node& current);

     Node& operator*() { return current(); }
     Node* operator->() { return &current(); }

     bool operator==(const ComposedTreeIterator& other) const { return context().iterator == other.context().iterator; }
     bool operator!=(const ComposedTreeIterator& other) const { return context().iterator != other.context().iterator; }

     ComposedTreeIterator& operator++() { return traverseNext(); }

     ComposedTreeIterator& traverseNext();
     ComposedTreeIterator& traverseNextSkippingChildren();
     ComposedTreeIterator& traverseNextSibling();
     ComposedTreeIterator& traversePreviousSibling();

     unsigned depth() const;

     void dropAssertions();

 private:
     void initializeContextStack(ContainerNode& root, Node& current);
     void traverseNextInShadowTree();
     void traverseNextLeavingContext();
     void traverseShadowRoot(ShadowRoot&);
     bool advanceInSlot(int direction);
     void traverseSiblingInSlot(int direction);

     struct Context {
         Context();
         Context(ContainerNode& root, FirstChildTag);
         Context(ContainerNode& root, Node& node);

         enum SlottedTag { Slotted };
         Context(ContainerNode& root, Node& node, SlottedTag);
         ElementAndTextDescendantIterator iterator;
         ElementAndTextDescendantIterator end;
         size_t slotNodeIndex { notFound };
     };
     Context& context() { return m_contextStack.last(); }
     const Context& context() const { return m_contextStack.last(); }
     Node& current() { return *context().iterator; }

     bool m_rootIsInShadowTree { false };
     bool m_didDropAssertions { false };
     Vector<Context, 8> m_contextStack;
 };

 inline ComposedTreeIterator::ComposedTreeIterator()
 {
     m_contextStack.uncheckedAppend({ });
 }

 inline ComposedTreeIterator& ComposedTreeIterator::traverseNext()
 {
     if (auto* shadowRoot = context().iterator->shadowRoot()) {
         traverseShadowRoot(*shadowRoot);
         return *this;
     }

     if (m_contextStack.size() > 1 || m_rootIsInShadowTree) {
         traverseNextInShadowTree();
         return *this;
     }

     context().iterator.traverseNext();
     return *this;
 }

 inline ComposedTreeIterator& ComposedTreeIterator::traverseNextSkippingChildren()
 {
     context().iterator.traverseNextSkippingChildren();

     if (context().iterator == context().end)
         traverseNextLeavingContext();

     return *this;
 }

 inline ComposedTreeIterator& ComposedTreeIterator::traverseNextSibling()
 {
     if (current().parentNode()->shadowRoot()) {
         traverseSiblingInSlot(1);
         return *this;
     }
     context().iterator.traverseNextSibling();
     return *this;
 }

 inline ComposedTreeIterator& ComposedTreeIterator::traversePreviousSibling()
 {
     if (current().parentNode()->shadowRoot()) {
         traverseSiblingInSlot(-1);
         return *this;
     }
     context().iterator.traversePreviousSibling();
     return *this;
 }

 inline unsigned ComposedTreeIterator::depth() const
 {
     unsigned depth = 0;
     for (auto& context : m_contextStack)
         depth += context.iterator.depth();
     return depth;
 }

 class ComposedTreeDescendantAdapter {
 public:
     ComposedTreeDescendantAdapter(ContainerNode& parent)
         : m_parent(parent)
     { }

     ComposedTreeIterator begin() { return ComposedTreeIterator(m_parent, ComposedTreeIterator::FirstChild); }
     ComposedTreeIterator end() { return { }; }
     ComposedTreeIterator at(const Node& child) { return ComposedTreeIterator(m_parent, const_cast<Node&>(child)); }

 private:
     ContainerNode& m_parent;
 };

 class ComposedTreeChildAdapter {
 public:
     class Iterator : public ComposedTreeIterator {
     public:
         Iterator() = default;
         explicit Iterator(ContainerNode& root)
             : ComposedTreeIterator(root, ComposedTreeIterator::FirstChild)
         { }
         Iterator(ContainerNode& root, Node& current)
             : ComposedTreeIterator(root, current)
         { }

         Iterator& operator++() { return static_cast<Iterator&>(traverseNextSibling()); }
         Iterator& operator--() { return static_cast<Iterator&>(traversePreviousSibling()); }
     };

     ComposedTreeChildAdapter(ContainerNode& parent)
         : m_parent(parent)
     { }

     Iterator begin() { return Iterator(m_parent); }
     Iterator end() { return { }; }
     Iterator at(const Node& child) { return Iterator(m_parent, const_cast<Node&>(child)); }

 private:
     ContainerNode& m_parent;
 };

 // FIXME: We should have const versions too.
 inline ComposedTreeDescendantAdapter composedTreeDescendants(ContainerNode& parent)
 {
     return ComposedTreeDescendantAdapter(parent);
 }

 inline ComposedTreeChildAdapter composedTreeChildren(ContainerNode& parent)
 {
     return ComposedTreeChildAdapter(parent);
 }

 enum class ComposedTreeAsTextMode { Normal, WithPointers };
 WEBCORE_EXPORT String composedTreeAsText(ContainerNode& root, ComposedTreeAsTextMode = ComposedTreeAsTextMode::Normal);


 // Helper functions for walking the composed tree.
 // FIXME: Use ComposedTreeIterator instead. These functions are more expensive because they might do O(n) work.

 inline HTMLSlotElement* assignedSlotIgnoringUserAgentShadow(Node& node)
 {
     auto* slot = node.assignedSlot();
     if (!slot || slot->containingShadowRoot()->mode() == ShadowRootMode::UserAgent)
         return nullptr;
     return slot;
 }

 inline ShadowRoot* shadowRootIgnoringUserAgentShadow(Node& node)
 {
     auto* shadowRoot = node.shadowRoot();
     if (!shadowRoot || shadowRoot->mode() == ShadowRootMode::UserAgent)
         return nullptr;
     return shadowRoot;
 }

 inline Node* firstChildInComposedTreeIgnoringUserAgentShadow(Node& node)
 {
     if (auto* shadowRoot = shadowRootIgnoringUserAgentShadow(node))
         return shadowRoot->firstChild();
     if (is<HTMLSlotElement>(node)) {
         if (auto* assignedNodes = downcast<HTMLSlotElement>(node).assignedNodes())
             return assignedNodes->at(0);
     }
     return node.firstChild();
 }

 inline Node* nextSiblingInComposedTreeIgnoringUserAgentShadow(Node& node)
 {
     if (auto* slot = assignedSlotIgnoringUserAgentShadow(node)) {
         auto* assignedNodes = slot->assignedNodes();
         ASSERT(assignedNodes);
         auto nodeIndex = assignedNodes->find(&node);
         ASSERT(nodeIndex != notFound);
         if (assignedNodes->size() > nodeIndex + 1)
             return assignedNodes->at(nodeIndex + 1);
         return nullptr;
     }
     return node.nextSibling();
 }

 inline Node* nextSkippingChildrenInComposedTreeIgnoringUserAgentShadow(Node& node)
 {
     if (auto* sibling = nextSiblingInComposedTreeIgnoringUserAgentShadow(node))
         return sibling;
     for (auto* ancestor = node.parentInComposedTree(); ancestor; ancestor = ancestor->parentInComposedTree()) {
         if (auto* sibling = nextSiblingInComposedTreeIgnoringUserAgentShadow(*ancestor))
             return sibling;
     }
     return nullptr;
 }

 inline Node* nextInComposedTreeIgnoringUserAgentShadow(Node& node)
 {
     if (auto* firstChild = firstChildInComposedTreeIgnoringUserAgentShadow(node))
         return firstChild;
     return nextSkippingChildrenInComposedTreeIgnoringUserAgentShadow(node);
 }

 } // namespace WebCore
	/*
	* Copyright (C) 2015-2016 Apple Inc. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
	* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
	* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
	* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#pragma once

	#include "ElementAndTextDescendantIterator.h"
	#include "HTMLSlotElement.h"
	#include "ShadowRoot.h"

	namespace WebCore {

	class HTMLSlotElement;

	class ComposedTreeIterator {
	public:
	ComposedTreeIterator();
	enum FirstChildTag { FirstChild };
	ComposedTreeIterator(ContainerNode& root, FirstChildTag);
	ComposedTreeIterator(ContainerNode& root, Node& current);

	Node& operator*() { return current(); }
	Node* operator->() { return &current(); }

	bool operator==(const ComposedTreeIterator& other) const { return context().iterator == other.context().iterator; }
	bool operator!=(const ComposedTreeIterator& other) const { return context().iterator != other.context().iterator; }

	ComposedTreeIterator& operator++() { return traverseNext(); }

	ComposedTreeIterator& traverseNext();
	ComposedTreeIterator& traverseNextSkippingChildren();
	ComposedTreeIterator& traverseNextSibling();
	ComposedTreeIterator& traversePreviousSibling();

	unsigned depth() const;

	void dropAssertions();

	private:
	void initializeContextStack(ContainerNode& root, Node& current);
	void traverseNextInShadowTree();
	void traverseNextLeavingContext();
	void traverseShadowRoot(ShadowRoot&);
	bool advanceInSlot(int direction);
	void traverseSiblingInSlot(int direction);

	struct Context {
	Context();
	Context(ContainerNode& root, FirstChildTag);
	Context(ContainerNode& root, Node& node);

	enum SlottedTag { Slotted };
	Context(ContainerNode& root, Node& node, SlottedTag);
	ElementAndTextDescendantIterator iterator;
	ElementAndTextDescendantIterator end;
	size_t slotNodeIndex { notFound };
	};
	Context& context() { return m_contextStack.last(); }
	const Context& context() const { return m_contextStack.last(); }
	Node& current() { return *context().iterator; }

	bool m_rootIsInShadowTree { false };
	bool m_didDropAssertions { false };
	Vector<Context, 8> m_contextStack;
	};

	inline ComposedTreeIterator::ComposedTreeIterator()
	{
	m_contextStack.uncheckedAppend({ });
	}

	inline ComposedTreeIterator& ComposedTreeIterator::traverseNext()
	{
	if (auto* shadowRoot = context().iterator->shadowRoot()) {
	traverseShadowRoot(*shadowRoot);
	return *this;
	}

	if (m_contextStack.size() > 1 \|\| m_rootIsInShadowTree) {
	traverseNextInShadowTree();
	return *this;
	}

	context().iterator.traverseNext();
	return *this;
	}

	inline ComposedTreeIterator& ComposedTreeIterator::traverseNextSkippingChildren()
	{
	context().iterator.traverseNextSkippingChildren();

	if (context().iterator == context().end)
	traverseNextLeavingContext();

	return *this;
	}

	inline ComposedTreeIterator& ComposedTreeIterator::traverseNextSibling()
	{
	if (current().parentNode()->shadowRoot()) {
	traverseSiblingInSlot(1);
	return *this;
	}
	context().iterator.traverseNextSibling();
	return *this;
	}

	inline ComposedTreeIterator& ComposedTreeIterator::traversePreviousSibling()
	{
	if (current().parentNode()->shadowRoot()) {
	traverseSiblingInSlot(-1);
	return *this;
	}
	context().iterator.traversePreviousSibling();
	return *this;
	}

	inline unsigned ComposedTreeIterator::depth() const
	{
	unsigned depth = 0;
	for (auto& context : m_contextStack)
	depth += context.iterator.depth();
	return depth;
	}

	class ComposedTreeDescendantAdapter {
	public:
	ComposedTreeDescendantAdapter(ContainerNode& parent)
	: m_parent(parent)
	{ }

	ComposedTreeIterator begin() { return ComposedTreeIterator(m_parent, ComposedTreeIterator::FirstChild); }
	ComposedTreeIterator end() { return { }; }
	ComposedTreeIterator at(const Node& child) { return ComposedTreeIterator(m_parent, const_cast<Node&>(child)); }

	private:
	ContainerNode& m_parent;
	};

	class ComposedTreeChildAdapter {
	public:
	class Iterator : public ComposedTreeIterator {
	public:
	Iterator() = default;
	explicit Iterator(ContainerNode& root)
	: ComposedTreeIterator(root, ComposedTreeIterator::FirstChild)
	{ }
	Iterator(ContainerNode& root, Node& current)
	: ComposedTreeIterator(root, current)
	{ }

	Iterator& operator++() { return static_cast<Iterator&>(traverseNextSibling()); }
	Iterator& operator--() { return static_cast<Iterator&>(traversePreviousSibling()); }
	};

	ComposedTreeChildAdapter(ContainerNode& parent)
	: m_parent(parent)
	{ }

	Iterator begin() { return Iterator(m_parent); }
	Iterator end() { return { }; }
	Iterator at(const Node& child) { return Iterator(m_parent, const_cast<Node&>(child)); }

	private:
	ContainerNode& m_parent;
	};

	// FIXME: We should have const versions too.
	inline ComposedTreeDescendantAdapter composedTreeDescendants(ContainerNode& parent)
	{
	return ComposedTreeDescendantAdapter(parent);
	}

	inline ComposedTreeChildAdapter composedTreeChildren(ContainerNode& parent)
	{
	return ComposedTreeChildAdapter(parent);
	}

	enum class ComposedTreeAsTextMode { Normal, WithPointers };
	WEBCORE_EXPORT String composedTreeAsText(ContainerNode& root, ComposedTreeAsTextMode = ComposedTreeAsTextMode::Normal);


	// Helper functions for walking the composed tree.
	// FIXME: Use ComposedTreeIterator instead. These functions are more expensive because they might do O(n) work.

	inline HTMLSlotElement* assignedSlotIgnoringUserAgentShadow(Node& node)
	{
	auto* slot = node.assignedSlot();
	if (!slot \|\| slot->containingShadowRoot()->mode() == ShadowRootMode::UserAgent)
	return nullptr;
	return slot;
	}

	inline ShadowRoot* shadowRootIgnoringUserAgentShadow(Node& node)
	{
	auto* shadowRoot = node.shadowRoot();
	if (!shadowRoot \|\| shadowRoot->mode() == ShadowRootMode::UserAgent)
	return nullptr;
	return shadowRoot;
	}

	inline Node* firstChildInComposedTreeIgnoringUserAgentShadow(Node& node)
	{
	if (auto* shadowRoot = shadowRootIgnoringUserAgentShadow(node))
	return shadowRoot->firstChild();
	if (is<HTMLSlotElement>(node)) {
	if (auto* assignedNodes = downcast<HTMLSlotElement>(node).assignedNodes())
	return assignedNodes->at(0);
	}
	return node.firstChild();
	}

	inline Node* nextSiblingInComposedTreeIgnoringUserAgentShadow(Node& node)
	{
	if (auto* slot = assignedSlotIgnoringUserAgentShadow(node)) {
	auto* assignedNodes = slot->assignedNodes();
	ASSERT(assignedNodes);
	auto nodeIndex = assignedNodes->find(&node);
	ASSERT(nodeIndex != notFound);
	if (assignedNodes->size() > nodeIndex + 1)
	return assignedNodes->at(nodeIndex + 1);
	return nullptr;
	}
	return node.nextSibling();
	}

	inline Node* nextSkippingChildrenInComposedTreeIgnoringUserAgentShadow(Node& node)
	{
	if (auto* sibling = nextSiblingInComposedTreeIgnoringUserAgentShadow(node))
	return sibling;
	for (auto* ancestor = node.parentInComposedTree(); ancestor; ancestor = ancestor->parentInComposedTree()) {
	if (auto* sibling = nextSiblingInComposedTreeIgnoringUserAgentShadow(*ancestor))
	return sibling;
	}
	return nullptr;
	}

	inline Node* nextInComposedTreeIgnoringUserAgentShadow(Node& node)
	{
	if (auto* firstChild = firstChildInComposedTreeIgnoringUserAgentShadow(node))
	return firstChild;
	return nextSkippingChildrenInComposedTreeIgnoringUserAgentShadow(node);
	}

	} // namespace WebCore