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webkit / WebKit / 198f43ca95a4a4b3336fbbd64fca37d7f72c06b5 / . / Source / WebCore / dom / ContainerNode.cpp
blob: fd53a2fadf7c1b6ba5b3780dc08e2e546f871975 [file] [log] [blame]
/*
* Copyright (C) 1999 Lars Knoll (knoll@kde.org)
* (C) 1999 Antti Koivisto (koivisto@kde.org)
* (C) 2001 Dirk Mueller (mueller@kde.org)
* Copyright (C) 2004, 2005, 2006, 2007, 2008, 2009 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 "config.h"
#include "ContainerNode.h"
#include "ChildListMutationScope.h"
#include "ContainerNodeAlgorithms.h"
#include "DeleteButtonController.h"
#include "EventNames.h"
#include "ExceptionCode.h"
#include "FloatRect.h"
#include "Frame.h"
#include "FrameView.h"
#include "InlineTextBox.h"
#include "InspectorInstrumentation.h"
#include "MemoryCache.h"
#include "MutationEvent.h"
#include "ResourceLoadScheduler.h"
#include "Page.h"
#include "RenderBox.h"
#include "RenderTheme.h"
#include "RootInlineBox.h"
#include <wtf/CurrentTime.h>
#include <wtf/Vector.h>
using namespace std;
namespace WebCore {
static void dispatchChildInsertionEvents(Node*);
static void dispatchChildRemovalEvents(Node*);
static void updateTreeAfterInsertion(ContainerNode*, Node*, bool shouldLazyAttach);
typedef pair<RefPtr<Node>, unsigned> CallbackParameters;
typedef pair<NodeCallback, CallbackParameters> CallbackInfo;
typedef Vector<CallbackInfo> NodeCallbackQueue;
static NodeCallbackQueue* s_postAttachCallbackQueue;
static size_t s_attachDepth;
static bool s_shouldReEnableMemoryCacheCallsAfterAttach;
static void collectTargetNodes(Node* node, NodeVector& nodes)
{
if (node->nodeType() != Node::DOCUMENT_FRAGMENT_NODE) {
nodes.append(node);
return;
}
getChildNodes(node, nodes);
}
static void collectChildrenAndRemoveFromOldParent(Node* node, NodeVector& nodes, ExceptionCode& ec)
{
if (node->nodeType() != Node::DOCUMENT_FRAGMENT_NODE) {
nodes.append(node);
if (ContainerNode* oldParent = node->parentNode())
oldParent->removeChild(node, ec);
return;
}
getChildNodes(node, nodes);
toContainerNode(node)->removeChildren();
}
void ContainerNode::removeAllChildren()
{
removeAllChildrenInContainer<Node, ContainerNode>(this);
}
void ContainerNode::takeAllChildrenFrom(ContainerNode* oldParent)
{
NodeVector children;
getChildNodes(oldParent, children);
oldParent->removeAllChildren();
for (unsigned i = 0; i < children.size(); ++i) {
ExceptionCode ec = 0;
if (children[i]->attached())
children[i]->detach();
// FIXME: We need a no mutation event version of adoptNode.
RefPtr<Node> child = document()->adoptNode(children[i].release(), ec);
ASSERT(!ec);
parserAddChild(child.get());
// FIXME: Together with adoptNode above, the tree scope might get updated recursively twice
// (if the document changed or oldParent was in a shadow tree, AND *this is in a shadow tree).
// Can we do better?
treeScope()->adoptIfNeeded(child.get());
if (attached() && !child->attached())
child->attach();
}
}
ContainerNode::~ContainerNode()
{
removeAllChildren();
}
bool ContainerNode::insertBefore(PassRefPtr<Node> newChild, Node* refChild, ExceptionCode& ec, bool shouldLazyAttach)
{
// Check that this node is not "floating".
// If it is, it can be deleted as a side effect of sending mutation events.
ASSERT(refCount() || parentOrHostNode());
RefPtr<Node> protect(this);
ec = 0;
// insertBefore(node, 0) is equivalent to appendChild(node)
if (!refChild)
return appendChild(newChild, ec, shouldLazyAttach);
// Make sure adding the new child is OK.
checkAddChild(newChild.get(), ec);
if (ec)
return false;
// NOT_FOUND_ERR: Raised if refChild is not a child of this node
if (refChild->parentNode() != this) {
ec = NOT_FOUND_ERR;
return false;
}
if (refChild->previousSibling() == newChild || refChild == newChild) // nothing to do
return true;
RefPtr<Node> next = refChild;
NodeVector targets;
collectChildrenAndRemoveFromOldParent(newChild.get(), targets, ec);
if (ec)
return false;
if (targets.isEmpty())
return true;
InspectorInstrumentation::willInsertDOMNode(document(), this);
#if ENABLE(MUTATION_OBSERVERS)
ChildListMutationScope mutation(this);
#endif
for (NodeVector::const_iterator it = targets.begin(); it != targets.end(); ++it) {
Node* child = it->get();
// Due to arbitrary code running in response to a DOM mutation event it's
// possible that "next" is no longer a child of "this".
// It's also possible that "child" has been inserted elsewhere.
// In either of those cases, we'll just stop.
if (next->parentNode() != this)
break;
if (child->parentNode())
break;
treeScope()->adoptIfNeeded(child);
insertBeforeCommon(next.get(), child);
updateTreeAfterInsertion(this, child, shouldLazyAttach);
}
dispatchSubtreeModifiedEvent();
return true;
}
void ContainerNode::insertBeforeCommon(Node* nextChild, Node* newChild)
{
ASSERT(newChild);
ASSERT(!newChild->parentNode()); // Use insertBefore if you need to handle reparenting (and want DOM mutation events).
ASSERT(!newChild->nextSibling());
ASSERT(!newChild->previousSibling());
ASSERT(!newChild->isShadowRoot());
forbidEventDispatch();
Node* prev = nextChild->previousSibling();
ASSERT(m_lastChild != prev);
nextChild->setPreviousSibling(newChild);
if (prev) {
ASSERT(m_firstChild != nextChild);
ASSERT(prev->nextSibling() == nextChild);
prev->setNextSibling(newChild);
} else {
ASSERT(m_firstChild == nextChild);
m_firstChild = newChild;
}
newChild->setParentOrHostNode(this);
newChild->setPreviousSibling(prev);
newChild->setNextSibling(nextChild);
allowEventDispatch();
}
void ContainerNode::parserInsertBefore(PassRefPtr<Node> newChild, Node* nextChild)
{
ASSERT(newChild);
ASSERT(nextChild);
ASSERT(nextChild->parentNode() == this);
NodeVector targets;
collectTargetNodes(newChild.get(), targets);
if (targets.isEmpty())
return;
if (nextChild->previousSibling() == newChild || nextChild == newChild) // nothing to do
return;
RefPtr<Node> next = nextChild;
RefPtr<Node> nextChildPreviousSibling = nextChild->previousSibling();
for (NodeVector::const_iterator it = targets.begin(); it != targets.end(); ++it) {
Node* child = it->get();
insertBeforeCommon(next.get(), child);
childrenChanged(true, nextChildPreviousSibling.get(), nextChild, 1);
ChildNodeInsertionNotifier(this).notify(child);
}
}
bool ContainerNode::replaceChild(PassRefPtr<Node> newChild, Node* oldChild, ExceptionCode& ec, bool shouldLazyAttach)
{
// Check that this node is not "floating".
// If it is, it can be deleted as a side effect of sending mutation events.
ASSERT(refCount() || parentOrHostNode());
RefPtr<Node> protect(this);
ec = 0;
if (oldChild == newChild) // nothing to do
return true;
// Make sure replacing the old child with the new is ok
checkReplaceChild(newChild.get(), oldChild, ec);
if (ec)
return false;
// NOT_FOUND_ERR: Raised if oldChild is not a child of this node.
if (!oldChild || oldChild->parentNode() != this) {
ec = NOT_FOUND_ERR;
return false;
}
#if ENABLE(MUTATION_OBSERVERS)
ChildListMutationScope mutation(this);
#endif
RefPtr<Node> next = oldChild->nextSibling();
// Remove the node we're replacing
RefPtr<Node> removedChild = oldChild;
removeChild(oldChild, ec);
if (ec)
return false;
if (next && (next->previousSibling() == newChild || next == newChild)) // nothing to do
return true;
NodeVector targets;
collectChildrenAndRemoveFromOldParent(newChild.get(), targets, ec);
if (ec)
return false;
InspectorInstrumentation::willInsertDOMNode(document(), this);
// Add the new child(ren)
for (NodeVector::const_iterator it = targets.begin(); it != targets.end(); ++it) {
Node* child = it->get();
// Due to arbitrary code running in response to a DOM mutation event it's
// possible that "next" is no longer a child of "this".
// It's also possible that "child" has been inserted elsewhere.
// In either of those cases, we'll just stop.
if (next && next->parentNode() != this)
break;
if (child->parentNode())
break;
treeScope()->adoptIfNeeded(child);
// Add child before "next".
forbidEventDispatch();
if (next)
insertBeforeCommon(next.get(), child);
else
appendChildToContainer(child, this);
allowEventDispatch();
updateTreeAfterInsertion(this, child, shouldLazyAttach);
}
dispatchSubtreeModifiedEvent();
return true;
}
static void willRemoveChild(Node* child)
{
#if ENABLE(MUTATION_OBSERVERS)
ASSERT(child->parentNode());
ChildListMutationScope(child->parentNode()).willRemoveChild(child);
child->notifyMutationObserversNodeWillDetach();
#endif
dispatchChildRemovalEvents(child);
child->document()->nodeWillBeRemoved(child); // e.g. mutation event listener can create a new range.
ChildFrameDisconnector(child).disconnect();
}
static void willRemoveChildren(ContainerNode* container)
{
NodeVector children;
getChildNodes(container, children);
container->document()->nodeChildrenWillBeRemoved(container);
#if ENABLE(MUTATION_OBSERVERS)
ChildListMutationScope mutation(container);
#endif
for (NodeVector::const_iterator it = children.begin(); it != children.end(); it++) {
Node* child = it->get();
#if ENABLE(MUTATION_OBSERVERS)
mutation.willRemoveChild(child);
child->notifyMutationObserversNodeWillDetach();
#endif
// fire removed from document mutation events.
dispatchChildRemovalEvents(child);
ChildFrameDisconnector(child).disconnect();
}
}
void ContainerNode::disconnectDescendantFrames()
{
ChildFrameDisconnector(this).disconnect();
}
bool ContainerNode::removeChild(Node* oldChild, ExceptionCode& ec)
{
// Check that this node is not "floating".
// If it is, it can be deleted as a side effect of sending mutation events.
ASSERT(refCount() || parentOrHostNode());
RefPtr<Node> protect(this);
ec = 0;
// NO_MODIFICATION_ALLOWED_ERR: Raised if this node is readonly.
if (isReadOnlyNode()) {
ec = NO_MODIFICATION_ALLOWED_ERR;
return false;
}
// NOT_FOUND_ERR: Raised if oldChild is not a child of this node.
if (!oldChild || oldChild->parentNode() != this) {
ec = NOT_FOUND_ERR;
return false;
}
RefPtr<Node> child = oldChild;
willRemoveChild(child.get());
// Mutation events might have moved this child into a different parent.
if (child->parentNode() != this) {
ec = NOT_FOUND_ERR;
return false;
}
document()->removeFocusedNodeOfSubtree(child.get());
#if ENABLE(FULLSCREEN_API)
document()->removeFullScreenElementOfSubtree(child.get());
#endif
// Events fired when blurring currently focused node might have moved this
// child into a different parent.
if (child->parentNode() != this) {
ec = NOT_FOUND_ERR;
return false;
}
Node* prev = child->previousSibling();
Node* next = child->nextSibling();
removeBetween(prev, next, child.get());
childrenChanged(false, prev, next, -1);
ChildNodeRemovalNotifier(this).notify(child.get());
dispatchSubtreeModifiedEvent();
return child;
}
void ContainerNode::removeBetween(Node* previousChild, Node* nextChild, Node* oldChild)
{
ASSERT(oldChild);
ASSERT(oldChild->parentNode() == this);
forbidEventDispatch();
// Remove from rendering tree
if (oldChild->attached())
oldChild->detach();
if (nextChild)
nextChild->setPreviousSibling(previousChild);
if (previousChild)
previousChild->setNextSibling(nextChild);
if (m_firstChild == oldChild)
m_firstChild = nextChild;
if (m_lastChild == oldChild)
m_lastChild = previousChild;
oldChild->setPreviousSibling(0);
oldChild->setNextSibling(0);
oldChild->setParentOrHostNode(0);
document()->adoptIfNeeded(oldChild);
allowEventDispatch();
}
void ContainerNode::parserRemoveChild(Node* oldChild)
{
ASSERT(oldChild);
ASSERT(oldChild->parentNode() == this);
Node* prev = oldChild->previousSibling();
Node* next = oldChild->nextSibling();
removeBetween(prev, next, oldChild);
childrenChanged(true, prev, next, -1);
ChildNodeRemovalNotifier(this).notify(oldChild);
}
// this differs from other remove functions because it forcibly removes all the children,
// regardless of read-only status or event exceptions, e.g.
void ContainerNode::removeChildren()
{
if (!m_firstChild)
return;
// The container node can be removed from event handlers.
RefPtr<ContainerNode> protect(this);
// Do any prep work needed before actually starting to detach
// and remove... e.g. stop loading frames, fire unload events.
willRemoveChildren(protect.get());
// exclude this node when looking for removed focusedNode since only children will be removed
document()->removeFocusedNodeOfSubtree(this, true);
#if ENABLE(FULLSCREEN_API)
document()->removeFullScreenElementOfSubtree(this, true);
#endif
forbidEventDispatch();
Vector<RefPtr<Node>, 10> removedChildren;
removedChildren.reserveInitialCapacity(childNodeCount());
while (RefPtr<Node> n = m_firstChild) {
Node* next = n->nextSibling();
// Remove the node from the tree before calling detach or removedFromDocument (4427024, 4129744).
// removeChild() does this after calling detach(). There is no explanation for
// this discrepancy between removeChild() and its optimized version removeChildren().
n->setPreviousSibling(0);
n->setNextSibling(0);
n->setParentOrHostNode(0);
document()->adoptIfNeeded(n.get());
m_firstChild = next;
if (n == m_lastChild)
m_lastChild = 0;
removedChildren.append(n.release());
}
size_t removedChildrenCount = removedChildren.size();
size_t i;
// Detach the nodes only after properly removed from the tree because
// a. detaching requires a proper DOM tree (for counters and quotes for
// example) and during the previous loop the next sibling still points to
// the node being removed while the node being removed does not point back
// and does not point to the same parent as its next sibling.
// b. destroying Renderers of standalone nodes is sometimes faster.
for (i = 0; i < removedChildrenCount; ++i) {
Node* removedChild = removedChildren[i].get();
if (removedChild->attached())
removedChild->detach();
}
childrenChanged(false, 0, 0, -static_cast<int>(removedChildrenCount));
for (i = 0; i < removedChildrenCount; ++i)
ChildNodeRemovalNotifier(this).notify(removedChildren[i].get());
allowEventDispatch();
dispatchSubtreeModifiedEvent();
}
bool ContainerNode::appendChild(PassRefPtr<Node> newChild, ExceptionCode& ec, bool shouldLazyAttach)
{
RefPtr<ContainerNode> protect(this);
// Check that this node is not "floating".
// If it is, it can be deleted as a side effect of sending mutation events.
ASSERT(refCount() || parentOrHostNode());
ec = 0;
// Make sure adding the new child is ok
checkAddChild(newChild.get(), ec);
if (ec)
return false;
if (newChild == m_lastChild) // nothing to do
return newChild;
NodeVector targets;
collectChildrenAndRemoveFromOldParent(newChild.get(), targets, ec);
if (ec)
return false;
if (targets.isEmpty())
return true;
InspectorInstrumentation::willInsertDOMNode(document(), this);
#if ENABLE(MUTATION_OBSERVERS)
ChildListMutationScope mutation(this);
#endif
// Now actually add the child(ren)
for (NodeVector::const_iterator it = targets.begin(); it != targets.end(); ++it) {
Node* child = it->get();
// If the child has a parent again, just stop what we're doing, because
// that means someone is doing something with DOM mutation -- can't re-parent
// a child that already has a parent.
if (child->parentNode())
break;
treeScope()->adoptIfNeeded(child);
// Append child to the end of the list
forbidEventDispatch();
appendChildToContainer(child, this);
allowEventDispatch();
updateTreeAfterInsertion(this, child, shouldLazyAttach);
}
dispatchSubtreeModifiedEvent();
return true;
}
void ContainerNode::parserAddChild(PassRefPtr<Node> newChild)
{
ASSERT(newChild);
ASSERT(!newChild->parentNode()); // Use appendChild if you need to handle reparenting (and want DOM mutation events).
forbidEventDispatch();
Node* last = m_lastChild;
// FIXME: This method should take a PassRefPtr.
appendChildToContainer(newChild.get(), this);
treeScope()->adoptIfNeeded(newChild.get());
allowEventDispatch();
childrenChanged(true, last, 0, 1);
ChildNodeInsertionNotifier(this).notify(newChild.get());
}
void ContainerNode::suspendPostAttachCallbacks()
{
if (!s_attachDepth) {
ASSERT(!s_shouldReEnableMemoryCacheCallsAfterAttach);
if (Page* page = document()->page()) {
// FIXME: How can this call be specific to one Page, while the
// s_attachDepth is a global? Doesn't make sense.
if (page->areMemoryCacheClientCallsEnabled()) {
page->setMemoryCacheClientCallsEnabled(false);
s_shouldReEnableMemoryCacheCallsAfterAttach = true;
}
}
resourceLoadScheduler()->suspendPendingRequests();
}
++s_attachDepth;
}
void ContainerNode::resumePostAttachCallbacks()
{
if (s_attachDepth == 1) {
RefPtr<ContainerNode> protect(this);
if (s_postAttachCallbackQueue)
dispatchPostAttachCallbacks();
if (s_shouldReEnableMemoryCacheCallsAfterAttach) {
s_shouldReEnableMemoryCacheCallsAfterAttach = false;
if (Page* page = document()->page())
page->setMemoryCacheClientCallsEnabled(true);
}
resourceLoadScheduler()->resumePendingRequests();
}
--s_attachDepth;
}
void ContainerNode::queuePostAttachCallback(NodeCallback callback, Node* node, unsigned callbackData)
{
if (!s_postAttachCallbackQueue)
s_postAttachCallbackQueue = new NodeCallbackQueue;
s_postAttachCallbackQueue->append(CallbackInfo(callback, CallbackParameters(node, callbackData)));
}
bool ContainerNode::postAttachCallbacksAreSuspended()
{
return s_attachDepth;
}
void ContainerNode::dispatchPostAttachCallbacks()
{
// We recalculate size() each time through the loop because a callback
// can add more callbacks to the end of the queue.
for (size_t i = 0; i < s_postAttachCallbackQueue->size(); ++i) {
const CallbackInfo& info = (*s_postAttachCallbackQueue)[i];
NodeCallback callback = info.first;
CallbackParameters params = info.second;
callback(params.first.get(), params.second);
}
s_postAttachCallbackQueue->clear();
}
static void needsStyleRecalcCallback(Node* node, unsigned data)
{
node->setNeedsStyleRecalc(static_cast<StyleChangeType>(data));
}
void ContainerNode::scheduleSetNeedsStyleRecalc(StyleChangeType changeType)
{
if (postAttachCallbacksAreSuspended())
queuePostAttachCallback(needsStyleRecalcCallback, this, static_cast<unsigned>(changeType));
else
setNeedsStyleRecalc(changeType);
}
void ContainerNode::attach()
{
attachChildren();
Node::attach();
}
void ContainerNode::detach()
{
detachChildren();
clearChildNeedsStyleRecalc();
Node::detach();
}
void ContainerNode::childrenChanged(bool changedByParser, Node*, Node*, int childCountDelta)
{
document()->incDOMTreeVersion();
if (!changedByParser && childCountDelta)
document()->updateRangesAfterChildrenChanged(this);
invalidateNodeListCachesInAncestors();
}
void ContainerNode::cloneChildNodes(ContainerNode *clone)
{
// disable the delete button so it's elements are not serialized into the markup
bool isEditorEnabled = false;
if (document()->frame() && document()->frame()->editor()->canEdit()) {
FrameSelection* selection = document()->frame()->selection();
Element* root = selection ? selection->rootEditableElement() : 0;
isEditorEnabled = root && isDescendantOf(root);
if (isEditorEnabled)
document()->frame()->editor()->deleteButtonController()->disable();
}
ExceptionCode ec = 0;
for (Node* n = firstChild(); n && !ec; n = n->nextSibling())
clone->appendChild(n->cloneNode(true), ec);
if (isEditorEnabled && document()->frame())
document()->frame()->editor()->deleteButtonController()->enable();
}
bool ContainerNode::getUpperLeftCorner(FloatPoint& point) const
{
if (!renderer())
return false;
// What is this code really trying to do?
RenderObject *o = renderer();
RenderObject *p = o;
if (!o->isInline() || o->isReplaced()) {
point = o->localToAbsolute(FloatPoint(), false, true);
return true;
}
// find the next text/image child, to get a position
while (o) {
p = o;
if (o->firstChild())
o = o->firstChild();
else if (o->nextSibling())
o = o->nextSibling();
else {
RenderObject *next = 0;
while (!next && o->parent()) {
o = o->parent();
next = o->nextSibling();
}
o = next;
if (!o)
break;
}
ASSERT(o);
if (!o->isInline() || o->isReplaced()) {
point = o->localToAbsolute(FloatPoint(), false, true);
return true;
}
if (p->node() && p->node() == this && o->isText() && !o->isBR() && !toRenderText(o)->firstTextBox()) {
// do nothing - skip unrendered whitespace that is a child or next sibling of the anchor
} else if ((o->isText() && !o->isBR()) || o->isReplaced()) {
point = FloatPoint();
if (o->isText() && toRenderText(o)->firstTextBox()) {
point.move(toRenderText(o)->linesBoundingBox().x(),
toRenderText(o)->firstTextBox()->root()->lineTop());
} else if (o->isBox()) {
RenderBox* box = toRenderBox(o);
point.moveBy(box->location());
}
point = o->container()->localToAbsolute(point, false, true);
return true;
}
}
// If the target doesn't have any children or siblings that could be used to calculate the scroll position, we must be
// at the end of the document. Scroll to the bottom. FIXME: who said anything about scrolling?
if (!o && document()->view()) {
point = FloatPoint(0, document()->view()->contentsHeight());
return true;
}
return false;
}
bool ContainerNode::getLowerRightCorner(FloatPoint& point) const
{
if (!renderer())
return false;
RenderObject* o = renderer();
if (!o->isInline() || o->isReplaced()) {
RenderBox* box = toRenderBox(o);
point = o->localToAbsolute(LayoutPoint(box->size()), false, true);
return true;
}
// find the last text/image child, to get a position
while (o) {
if (o->lastChild())
o = o->lastChild();
else if (o->previousSibling())
o = o->previousSibling();
else {
RenderObject* prev = 0;
while (!prev) {
o = o->parent();
if (!o)
return false;
prev = o->previousSibling();
}
o = prev;
}
ASSERT(o);
if (o->isText() || o->isReplaced()) {
point = FloatPoint();
if (o->isText()) {
RenderText* text = toRenderText(o);
IntRect linesBox = text->linesBoundingBox();
if (!linesBox.maxX() && !linesBox.maxY())
continue;
point.moveBy(linesBox.maxXMaxYCorner());
} else {
RenderBox* box = toRenderBox(o);
point.moveBy(box->frameRect().maxXMaxYCorner());
}
point = o->container()->localToAbsolute(point, false, true);
return true;
}
}
return true;
}
LayoutRect ContainerNode::getRect() const
{
FloatPoint upperLeft, lowerRight;
bool foundUpperLeft = getUpperLeftCorner(upperLeft);
bool foundLowerRight = getLowerRightCorner(lowerRight);
// If we've found one corner, but not the other,
// then we should just return a point at the corner that we did find.
if (foundUpperLeft != foundLowerRight) {
if (foundUpperLeft)
lowerRight = upperLeft;
else
upperLeft = lowerRight;
}
return enclosingLayoutRect(FloatRect(upperLeft, lowerRight.expandedTo(upperLeft) - upperLeft));
}
void ContainerNode::setFocus(bool received)
{
if (focused() == received)
return;
Node::setFocus(received);
// note that we need to recalc the style
setNeedsStyleRecalc();
}
void ContainerNode::setActive(bool down, bool pause)
{
if (down == active()) return;
Node::setActive(down);
// note that we need to recalc the style
// FIXME: Move to Element
if (renderer()) {
bool reactsToPress = renderer()->style()->affectedByActiveRules();
if (reactsToPress)
setNeedsStyleRecalc();
if (renderer() && renderer()->style()->hasAppearance()) {
if (renderer()->theme()->stateChanged(renderer(), PressedState))
reactsToPress = true;
}
if (reactsToPress && pause) {
// The delay here is subtle. It relies on an assumption, namely that the amount of time it takes
// to repaint the "down" state of the control is about the same time as it would take to repaint the
// "up" state. Once you assume this, you can just delay for 100ms - that time (assuming that after you
// leave this method, it will be about that long before the flush of the up state happens again).
#ifdef HAVE_FUNC_USLEEP
double startTime = currentTime();
#endif
// Ensure there are no pending changes
Document::updateStyleForAllDocuments();
// Do an immediate repaint.
if (renderer())
renderer()->repaint(true);
// FIXME: Find a substitute for usleep for Win32.
// Better yet, come up with a way of doing this that doesn't use this sort of thing at all.
#ifdef HAVE_FUNC_USLEEP
// Now pause for a small amount of time (1/10th of a second from before we repainted in the pressed state)
double remainingTime = 0.1 - (currentTime() - startTime);
if (remainingTime > 0)
usleep(static_cast<useconds_t>(remainingTime * 1000000.0));
#endif
}
}
}
void ContainerNode::setHovered(bool over)
{
if (over == hovered()) return;
Node::setHovered(over);
// note that we need to recalc the style
// FIXME: Move to Element
if (renderer()) {
if (renderer()->style()->affectedByHoverRules())
setNeedsStyleRecalc();
if (renderer() && renderer()->style()->hasAppearance())
renderer()->theme()->stateChanged(renderer(), HoverState);
}
}
unsigned ContainerNode::childNodeCount() const
{
unsigned count = 0;
Node *n;
for (n = firstChild(); n; n = n->nextSibling())
count++;
return count;
}
Node *ContainerNode::childNode(unsigned index) const
{
unsigned i;
Node *n = firstChild();
for (i = 0; n != 0 && i < index; i++)
n = n->nextSibling();
return n;
}
static void dispatchChildInsertionEvents(Node* child)
{
if (child->isInShadowTree())
return;
ASSERT(!eventDispatchForbidden());
RefPtr<Node> c = child;
RefPtr<Document> document = child->document();
if (c->parentNode() && document->hasListenerType(Document::DOMNODEINSERTED_LISTENER))
c->dispatchScopedEvent(MutationEvent::create(eventNames().DOMNodeInsertedEvent, true, c->parentNode()));
// dispatch the DOMNodeInsertedIntoDocument event to all descendants
if (c->inDocument() && document->hasListenerType(Document::DOMNODEINSERTEDINTODOCUMENT_LISTENER)) {
for (; c; c = c->traverseNextNode(child))
c->dispatchScopedEvent(MutationEvent::create(eventNames().DOMNodeInsertedIntoDocumentEvent, false));
}
}
static void dispatchChildRemovalEvents(Node* child)
{
if (child->isInShadowTree())
return;
ASSERT(!eventDispatchForbidden());
InspectorInstrumentation::willRemoveDOMNode(child->document(), child);
RefPtr<Node> c = child;
RefPtr<Document> document = child->document();
// dispatch pre-removal mutation events
if (c->parentNode() && document->hasListenerType(Document::DOMNODEREMOVED_LISTENER))
c->dispatchScopedEvent(MutationEvent::create(eventNames().DOMNodeRemovedEvent, true, c->parentNode()));
// dispatch the DOMNodeRemovedFromDocument event to all descendants
if (c->inDocument() && document->hasListenerType(Document::DOMNODEREMOVEDFROMDOCUMENT_LISTENER)) {
for (; c; c = c->traverseNextNode(child))
c->dispatchScopedEvent(MutationEvent::create(eventNames().DOMNodeRemovedFromDocumentEvent, false));
}
}
static void updateTreeAfterInsertion(ContainerNode* parent, Node* child, bool shouldLazyAttach)
{
ASSERT(parent->refCount());
ASSERT(child->refCount());
#if ENABLE(MUTATION_OBSERVERS)
ChildListMutationScope(parent).childAdded(child);
#endif
parent->childrenChanged(false, child->previousSibling(), child->nextSibling(), 1);
ChildNodeInsertionNotifier(parent).notify(child);
// FIXME: Attachment should be the first operation in this function, but some code
// (for example, HTMLFormControlElement's autofocus support) requires this ordering.
if (parent->attached() && !child->attached() && child->parentNode() == parent) {
if (shouldLazyAttach)
child->lazyAttach();
else
child->attach();
}
dispatchChildInsertionEvents(child);
}
} // namespace WebCore