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webkit / WebKit / 6c593ced07c8fda235ab6efb0c72e2dcfc438bc2 / . / Source / WebCore / svg / animation / SVGSMILElement.cpp
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/*
* Copyright (C) 2008 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.
*/
#include "config.h"
#include "SVGSMILElement.h"
#include "CSSPropertyNames.h"
#include "Document.h"
#include "Event.h"
#include "EventListener.h"
#include "EventNames.h"
#include "EventSender.h"
#include "FloatConversion.h"
#include "FrameView.h"
#include "SMILTimeContainer.h"
#include "SVGDocumentExtensions.h"
#include "SVGNames.h"
#include "SVGParserUtilities.h"
#include "SVGSVGElement.h"
#include "SVGURIReference.h"
#include "SVGUseElement.h"
#include "XLinkNames.h"
#include <wtf/IsoMallocInlines.h>
#include <wtf/MathExtras.h>
#include <wtf/StdLibExtras.h>
#include <wtf/Vector.h>
namespace WebCore {
WTF_MAKE_ISO_ALLOCATED_IMPL(SVGSMILElement);
static SMILEventSender& smilBeginEventSender()
{
static NeverDestroyed<SMILEventSender> sender(eventNames().beginEventEvent);
return sender;
}
static SMILEventSender& smilEndEventSender()
{
static NeverDestroyed<SMILEventSender> sender(eventNames().endEventEvent);
return sender;
}
// This is used for duration type time values that can't be negative.
static const double invalidCachedTime = -1.;
class ConditionEventListener final : public EventListener {
public:
static Ref<ConditionEventListener> create(SVGSMILElement* animation, SVGSMILElement::Condition* condition)
{
return adoptRef(*new ConditionEventListener(animation, condition));
}
static const ConditionEventListener* cast(const EventListener* listener)
{
return listener->type() == ConditionEventListenerType
? static_cast<const ConditionEventListener*>(listener)
: nullptr;
}
bool operator==(const EventListener& other) const final;
void disconnectAnimation()
{
m_animation = nullptr;
}
private:
ConditionEventListener(SVGSMILElement* animation, SVGSMILElement::Condition* condition)
: EventListener(ConditionEventListenerType)
, m_animation(animation)
, m_condition(condition)
{
}
void handleEvent(ScriptExecutionContext&, Event&) final;
SVGSMILElement* m_animation;
SVGSMILElement::Condition* m_condition;
};
bool ConditionEventListener::operator==(const EventListener& listener) const
{
if (const ConditionEventListener* conditionEventListener = ConditionEventListener::cast(&listener))
return m_animation == conditionEventListener->m_animation && m_condition == conditionEventListener->m_condition;
return false;
}
void ConditionEventListener::handleEvent(ScriptExecutionContext&, Event&)
{
if (!m_animation)
return;
m_animation->handleConditionEvent(m_condition);
}
SVGSMILElement::Condition::Condition(Type type, BeginOrEnd beginOrEnd, const String& baseID, const String& name, SMILTime offset, int repeats)
: m_type(type)
, m_beginOrEnd(beginOrEnd)
, m_baseID(baseID)
, m_name(name)
, m_offset(offset)
, m_repeats(repeats)
{
}
SVGSMILElement::SVGSMILElement(const QualifiedName& tagName, Document& doc)
: SVGElement(tagName, doc)
, m_attributeName(anyQName())
, m_targetElement(nullptr)
, m_conditionsConnected(false)
, m_hasEndEventConditions(false)
, m_isWaitingForFirstInterval(true)
, m_intervalBegin(SMILTime::unresolved())
, m_intervalEnd(SMILTime::unresolved())
, m_previousIntervalBegin(SMILTime::unresolved())
, m_activeState(Inactive)
, m_lastPercent(0)
, m_lastRepeat(0)
, m_nextProgressTime(0)
, m_documentOrderIndex(0)
, m_cachedDur(invalidCachedTime)
, m_cachedRepeatDur(invalidCachedTime)
, m_cachedRepeatCount(invalidCachedTime)
, m_cachedMin(invalidCachedTime)
, m_cachedMax(invalidCachedTime)
{
resolveFirstInterval();
}
SVGSMILElement::~SVGSMILElement()
{
clearResourceReferences();
smilBeginEventSender().cancelEvent(*this);
smilEndEventSender().cancelEvent(*this);
disconnectConditions();
if (m_timeContainer && m_targetElement && hasValidAttributeName())
m_timeContainer->unschedule(this, m_targetElement, m_attributeName);
}
void SVGSMILElement::clearResourceReferences()
{
document().accessSVGExtensions().removeAllTargetReferencesForElement(*this);
}
void SVGSMILElement::clearTarget()
{
setTargetElement(nullptr);
}
void SVGSMILElement::buildPendingResource()
{
clearResourceReferences();
if (!isConnected()) {
// Reset the target element if we are no longer in the document.
setTargetElement(nullptr);
return;
}
String id;
RefPtr<Element> target;
auto& href = getAttribute(SVGNames::hrefAttr, XLinkNames::hrefAttr);
if (href.isEmpty())
target = parentElement();
else {
auto result = SVGURIReference::targetElementFromIRIString(href.string(), treeScope());
target = WTFMove(result.element);
id = WTFMove(result.identifier);
}
SVGElement* svgTarget = is<SVGElement>(target) ? downcast<SVGElement>(target.get()) : nullptr;
if (svgTarget && !svgTarget->isConnected())
svgTarget = nullptr;
if (svgTarget != targetElement())
setTargetElement(svgTarget);
if (!svgTarget) {
// Do not register as pending if we are already pending this resource.
if (document().accessSVGExtensions().isPendingResource(*this, id))
return;
if (!id.isEmpty()) {
document().accessSVGExtensions().addPendingResource(id, *this);
ASSERT(hasPendingResources());
}
} else {
// Register us with the target in the dependencies map. Any change of hrefElement
// that leads to relayout/repainting now informs us, so we can react to it.
document().accessSVGExtensions().addElementReferencingTarget(*this, *svgTarget);
}
}
inline QualifiedName SVGSMILElement::constructAttributeName() const
{
auto parseResult = Document::parseQualifiedName(attributeWithoutSynchronization(SVGNames::attributeNameAttr));
if (parseResult.hasException())
return anyQName();
auto [prefix, localName] = parseResult.releaseReturnValue();
if (prefix.isNull())
return { nullAtom(), localName, nullAtom() };
auto namespaceURI = lookupNamespaceURI(prefix);
if (namespaceURI.isEmpty())
return anyQName();
return { nullAtom(), localName, namespaceURI };
}
inline void SVGSMILElement::updateAttributeName()
{
setAttributeName(constructAttributeName());
}
static inline void clearTimesWithDynamicOrigins(Vector<SMILTimeWithOrigin>& timeList)
{
timeList.removeAllMatching([] (const SMILTimeWithOrigin& time) {
return time.originIsScript();
});
}
void SVGSMILElement::reset()
{
clearAnimatedType(m_targetElement);
m_activeState = Inactive;
m_isWaitingForFirstInterval = true;
m_intervalBegin = SMILTime::unresolved();
m_intervalEnd = SMILTime::unresolved();
m_previousIntervalBegin = SMILTime::unresolved();
m_lastPercent = 0;
m_lastRepeat = 0;
m_nextProgressTime = 0;
resolveFirstInterval();
}
Node::InsertedIntoAncestorResult SVGSMILElement::insertedIntoAncestor(InsertionType insertionType, ContainerNode& parentOfInsertedTree)
{
SVGElement::insertedIntoAncestor(insertionType, parentOfInsertedTree);
if (!insertionType.connectedToDocument)
return InsertedIntoAncestorResult::Done;
// Verify we are not in <use> instance tree.
ASSERT(!isInShadowTree() || !is<SVGUseElement>(shadowHost()));
updateAttributeName();
auto owner = makeRefPtr(ownerSVGElement());
if (!owner)
return InsertedIntoAncestorResult::Done;
m_timeContainer = &owner->timeContainer();
m_timeContainer->setDocumentOrderIndexesDirty();
// "If no attribute is present, the default begin value (an offset-value of 0) must be evaluated."
if (!hasAttributeWithoutSynchronization(SVGNames::beginAttr))
m_beginTimes.append(SMILTimeWithOrigin());
if (m_isWaitingForFirstInterval)
resolveFirstInterval();
if (m_timeContainer)
m_timeContainer->notifyIntervalsChanged();
return InsertedIntoAncestorResult::NeedsPostInsertionCallback;
}
void SVGSMILElement::didFinishInsertingNode()
{
buildPendingResource();
}
void SVGSMILElement::removedFromAncestor(RemovalType removalType, ContainerNode& oldParentOfRemovedTree)
{
if (removalType.disconnectedFromDocument) {
clearResourceReferences();
disconnectConditions();
setTargetElement(nullptr);
setAttributeName(anyQName());
animationAttributeChanged();
m_timeContainer = nullptr;
}
SVGElement::removedFromAncestor(removalType, oldParentOfRemovedTree);
}
bool SVGSMILElement::hasValidAttributeName() const
{
return attributeName() != anyQName();
}
SMILTime SVGSMILElement::parseOffsetValue(const String& data)
{
bool ok;
double result = 0;
String parse = data.stripWhiteSpace();
if (parse.endsWith('h'))
result = parse.left(parse.length() - 1).toDouble(&ok) * 60 * 60;
else if (parse.endsWith("min"))
result = parse.left(parse.length() - 3).toDouble(&ok) * 60;
else if (parse.endsWith("ms"))
result = parse.left(parse.length() - 2).toDouble(&ok) / 1000;
else if (parse.endsWith('s'))
result = parse.left(parse.length() - 1).toDouble(&ok);
else
result = parse.toDouble(&ok);
if (!ok || !SMILTime(result).isFinite())
return SMILTime::unresolved();
return result;
}
SMILTime SVGSMILElement::parseClockValue(const String& data)
{
if (data.isNull())
return SMILTime::unresolved();
String parse = data.stripWhiteSpace();
static NeverDestroyed<const AtomString> indefiniteValue("indefinite", AtomString::ConstructFromLiteral);
if (parse == indefiniteValue)
return SMILTime::indefinite();
double result = 0;
bool ok;
size_t doublePointOne = parse.find(':');
size_t doublePointTwo = parse.find(':', doublePointOne + 1);
if (doublePointOne == 2 && doublePointTwo == 5 && parse.length() >= 8) {
result += parse.substring(0, 2).toUIntStrict(&ok) * 60 * 60;
if (!ok)
return SMILTime::unresolved();
result += parse.substring(3, 2).toUIntStrict(&ok) * 60;
if (!ok)
return SMILTime::unresolved();
result += parse.substring(6).toDouble(&ok);
} else if (doublePointOne == 2 && doublePointTwo == notFound && parse.length() >= 5) {
result += parse.substring(0, 2).toUIntStrict(&ok) * 60;
if (!ok)
return SMILTime::unresolved();
result += parse.substring(3).toDouble(&ok);
} else
return parseOffsetValue(parse);
if (!ok || !SMILTime(result).isFinite())
return SMILTime::unresolved();
return result;
}
static void sortTimeList(Vector<SMILTimeWithOrigin>& timeList)
{
std::sort(timeList.begin(), timeList.end());
}
bool SVGSMILElement::parseCondition(const String& value, BeginOrEnd beginOrEnd)
{
String parseString = value.stripWhiteSpace();
double sign = 1.;
bool ok;
size_t pos = parseString.find('+');
if (pos == notFound) {
pos = parseString.find('-');
if (pos != notFound)
sign = -1.;
}
String conditionString;
SMILTime offset = 0;
if (pos == notFound)
conditionString = parseString;
else {
conditionString = parseString.left(pos).stripWhiteSpace();
String offsetString = parseString.substring(pos + 1).stripWhiteSpace();
offset = parseOffsetValue(offsetString);
if (offset.isUnresolved())
return false;
offset = offset * sign;
}
if (conditionString.isEmpty())
return false;
pos = conditionString.find('.');
String baseID;
String nameString;
if (pos == notFound)
nameString = conditionString;
else {
baseID = conditionString.left(pos);
nameString = conditionString.substring(pos + 1);
}
if (nameString.isEmpty())
return false;
Condition::Type type;
int repeats = -1;
if (nameString.startsWith("repeat(") && nameString.endsWith(')')) {
// FIXME: For repeat events we just need to add the data carrying TimeEvent class and
// fire the events at appropiate times.
repeats = nameString.substring(7, nameString.length() - 8).toUIntStrict(&ok);
if (!ok)
return false;
nameString = "repeat";
type = Condition::EventBase;
} else if (nameString == "begin" || nameString == "end") {
if (baseID.isEmpty())
return false;
type = Condition::Syncbase;
} else if (nameString.startsWith("accesskey(")) {
// FIXME: accesskey() support.
type = Condition::AccessKey;
} else
type = Condition::EventBase;
m_conditions.append(Condition(type, beginOrEnd, baseID, nameString, offset, repeats));
if (type == Condition::EventBase && beginOrEnd == End)
m_hasEndEventConditions = true;
return true;
}
void SVGSMILElement::parseBeginOrEnd(const String& parseString, BeginOrEnd beginOrEnd)
{
Vector<SMILTimeWithOrigin>& timeList = beginOrEnd == Begin ? m_beginTimes : m_endTimes;
if (beginOrEnd == End)
m_hasEndEventConditions = false;
HashSet<double> existing;
for (auto& time : timeList)
existing.add(time.time().value());
for (auto& string : parseString.split(';')) {
SMILTime value = parseClockValue(string);
if (value.isUnresolved())
parseCondition(string, beginOrEnd);
else if (!existing.contains(value.value()))
timeList.append(SMILTimeWithOrigin(value, SMILTimeWithOrigin::ParserOrigin));
}
sortTimeList(timeList);
}
bool SVGSMILElement::isSupportedAttribute(const QualifiedName& attrName)
{
static const auto supportedAttributes = makeNeverDestroyed(HashSet<QualifiedName> {
SVGNames::beginAttr,
SVGNames::endAttr,
SVGNames::durAttr,
SVGNames::repeatDurAttr,
SVGNames::repeatCountAttr,
SVGNames::minAttr,
SVGNames::maxAttr,
SVGNames::attributeNameAttr,
SVGNames::hrefAttr,
XLinkNames::hrefAttr,
});
return supportedAttributes.get().contains<SVGAttributeHashTranslator>(attrName);
}
void SVGSMILElement::parseAttribute(const QualifiedName& name, const AtomString& value)
{
if (name == SVGNames::beginAttr) {
if (!m_conditions.isEmpty()) {
disconnectConditions();
m_conditions.clear();
parseBeginOrEnd(attributeWithoutSynchronization(SVGNames::endAttr), End);
}
parseBeginOrEnd(value.string(), Begin);
if (isConnected())
connectConditions();
} else if (name == SVGNames::endAttr) {
if (!m_conditions.isEmpty()) {
disconnectConditions();
m_conditions.clear();
parseBeginOrEnd(attributeWithoutSynchronization(SVGNames::beginAttr), Begin);
}
parseBeginOrEnd(value.string(), End);
if (isConnected())
connectConditions();
} else if (name == SVGNames::onendAttr)
setAttributeEventListener(eventNames().endEventEvent, name, value);
else if (name == SVGNames::onbeginAttr)
setAttributeEventListener(eventNames().beginEventEvent, name, value);
else
SVGElement::parseAttribute(name, value);
}
void SVGSMILElement::svgAttributeChanged(const QualifiedName& attrName)
{
if (!isSupportedAttribute(attrName)) {
SVGElement::svgAttributeChanged(attrName);
return;
}
if (attrName == SVGNames::durAttr)
m_cachedDur = invalidCachedTime;
else if (attrName == SVGNames::repeatDurAttr)
m_cachedRepeatDur = invalidCachedTime;
else if (attrName == SVGNames::repeatCountAttr)
m_cachedRepeatCount = invalidCachedTime;
else if (attrName == SVGNames::minAttr)
m_cachedMin = invalidCachedTime;
else if (attrName == SVGNames::maxAttr)
m_cachedMax = invalidCachedTime;
else if (attrName == SVGNames::attributeNameAttr)
updateAttributeName();
else if (attrName.matches(SVGNames::hrefAttr) || attrName.matches(XLinkNames::hrefAttr)) {
InstanceInvalidationGuard guard(*this);
buildPendingResource();
} else if (isConnected()) {
if (attrName == SVGNames::beginAttr)
beginListChanged(elapsed());
else if (attrName == SVGNames::endAttr)
endListChanged(elapsed());
}
animationAttributeChanged();
}
inline Element* SVGSMILElement::eventBaseFor(const Condition& condition)
{
return condition.m_baseID.isEmpty() ? targetElement() : treeScope().getElementById(condition.m_baseID);
}
void SVGSMILElement::connectConditions()
{
if (m_conditionsConnected)
disconnectConditions();
m_conditionsConnected = true;
for (auto& condition : m_conditions) {
if (condition.m_type == Condition::EventBase) {
ASSERT(!condition.m_syncbase);
auto eventBase = makeRefPtr(eventBaseFor(condition));
if (!eventBase)
continue;
ASSERT(!condition.m_eventListener);
condition.m_eventListener = ConditionEventListener::create(this, &condition);
eventBase->addEventListener(condition.m_name, *condition.m_eventListener, false);
} else if (condition.m_type == Condition::Syncbase) {
ASSERT(!condition.m_baseID.isEmpty());
condition.m_syncbase = treeScope().getElementById(condition.m_baseID);
if (!condition.m_syncbase)
continue;
if (!is<SVGSMILElement>(*condition.m_syncbase)) {
condition.m_syncbase = nullptr;
continue;
}
downcast<SVGSMILElement>(*condition.m_syncbase).addTimeDependent(this);
}
}
}
void SVGSMILElement::disconnectConditions()
{
if (!m_conditionsConnected)
return;
m_conditionsConnected = false;
for (auto& condition : m_conditions) {
if (condition.m_type == Condition::EventBase) {
ASSERT(!condition.m_syncbase);
if (!condition.m_eventListener)
continue;
// Note: It's a memory optimization to try to remove our condition
// event listener, but it's not guaranteed to work, since we have
// no guarantee that eventBaseFor() will be able to find our condition's
// original eventBase. So, we also have to disconnect ourselves from
// our condition event listener, in case it later fires.
auto eventBase = makeRefPtr(eventBaseFor(condition));
if (eventBase)
eventBase->removeEventListener(condition.m_name, *condition.m_eventListener, false);
condition.m_eventListener->disconnectAnimation();
condition.m_eventListener = nullptr;
} else if (condition.m_type == Condition::Syncbase) {
if (condition.m_syncbase)
downcast<SVGSMILElement>(condition.m_syncbase.get())->removeTimeDependent(this);
}
condition.m_syncbase = nullptr;
}
}
void SVGSMILElement::setAttributeName(const QualifiedName& attributeName)
{
if (m_timeContainer && m_targetElement && m_attributeName != attributeName) {
if (hasValidAttributeName())
m_timeContainer->unschedule(this, m_targetElement, m_attributeName);
m_attributeName = attributeName;
if (hasValidAttributeName())
m_timeContainer->schedule(this, m_targetElement, m_attributeName);
} else
m_attributeName = attributeName;
// Only clear the animated type, if we had a target before.
if (m_targetElement)
clearAnimatedType(m_targetElement);
}
void SVGSMILElement::setTargetElement(SVGElement* target)
{
if (m_timeContainer && hasValidAttributeName()) {
if (m_targetElement)
m_timeContainer->unschedule(this, m_targetElement, m_attributeName);
if (target)
m_timeContainer->schedule(this, target, m_attributeName);
}
if (m_targetElement) {
// Clear values that may depend on the previous target.
clearAnimatedType(m_targetElement);
disconnectConditions();
}
// If the animation state is not Inactive, always reset to a clear state before leaving the old target element.
if (m_activeState != Inactive)
endedActiveInterval();
m_targetElement = target;
}
SMILTime SVGSMILElement::elapsed() const
{
return m_timeContainer ? m_timeContainer->elapsed() : 0;
}
bool SVGSMILElement::isInactive() const
{
return m_activeState == Inactive;
}
bool SVGSMILElement::isFrozen() const
{
return m_activeState == Frozen;
}
SVGSMILElement::Restart SVGSMILElement::restart() const
{
static NeverDestroyed<const AtomString> never("never", AtomString::ConstructFromLiteral);
static NeverDestroyed<const AtomString> whenNotActive("whenNotActive", AtomString::ConstructFromLiteral);
const AtomString& value = attributeWithoutSynchronization(SVGNames::restartAttr);
if (value == never)
return RestartNever;
if (value == whenNotActive)
return RestartWhenNotActive;
return RestartAlways;
}
SVGSMILElement::FillMode SVGSMILElement::fill() const
{
static NeverDestroyed<const AtomString> freeze("freeze", AtomString::ConstructFromLiteral);
const AtomString& value = attributeWithoutSynchronization(SVGNames::fillAttr);
return value == freeze ? FillFreeze : FillRemove;
}
SMILTime SVGSMILElement::dur() const
{
if (m_cachedDur != invalidCachedTime)
return m_cachedDur;
const AtomString& value = attributeWithoutSynchronization(SVGNames::durAttr);
SMILTime clockValue = parseClockValue(value);
return m_cachedDur = clockValue <= 0 ? SMILTime::unresolved() : clockValue;
}
SMILTime SVGSMILElement::repeatDur() const
{
if (m_cachedRepeatDur != invalidCachedTime)
return m_cachedRepeatDur;
const AtomString& value = attributeWithoutSynchronization(SVGNames::repeatDurAttr);
SMILTime clockValue = parseClockValue(value);
m_cachedRepeatDur = clockValue <= 0 ? SMILTime::unresolved() : clockValue;
return m_cachedRepeatDur;
}
// So a count is not really a time but let just all pretend we did not notice.
SMILTime SVGSMILElement::repeatCount() const
{
if (m_cachedRepeatCount != invalidCachedTime)
return m_cachedRepeatCount;
const AtomString& value = attributeWithoutSynchronization(SVGNames::repeatCountAttr);
if (value.isNull())
return SMILTime::unresolved();
static NeverDestroyed<const AtomString> indefiniteValue("indefinite", AtomString::ConstructFromLiteral);
if (value == indefiniteValue)
return SMILTime::indefinite();
bool ok;
double result = value.string().toDouble(&ok);
return m_cachedRepeatCount = ok && result > 0 ? result : SMILTime::unresolved();
}
SMILTime SVGSMILElement::maxValue() const
{
if (m_cachedMax != invalidCachedTime)
return m_cachedMax;
const AtomString& value = attributeWithoutSynchronization(SVGNames::maxAttr);
SMILTime result = parseClockValue(value);
return m_cachedMax = (result.isUnresolved() || result <= 0) ? SMILTime::indefinite() : result;
}
SMILTime SVGSMILElement::minValue() const
{
if (m_cachedMin != invalidCachedTime)
return m_cachedMin;
const AtomString& value = attributeWithoutSynchronization(SVGNames::minAttr);
SMILTime result = parseClockValue(value);
return m_cachedMin = (result.isUnresolved() || result < 0) ? 0 : result;
}
SMILTime SVGSMILElement::simpleDuration() const
{
return std::min(dur(), SMILTime::indefinite());
}
void SVGSMILElement::addBeginTime(SMILTime eventTime, SMILTime beginTime, SMILTimeWithOrigin::Origin origin)
{
ASSERT(!std::isnan(beginTime.value()));
m_beginTimes.append(SMILTimeWithOrigin(beginTime, origin));
sortTimeList(m_beginTimes);
beginListChanged(eventTime);
}
void SVGSMILElement::addEndTime(SMILTime eventTime, SMILTime endTime, SMILTimeWithOrigin::Origin origin)
{
ASSERT(!std::isnan(endTime.value()));
m_endTimes.append(SMILTimeWithOrigin(endTime, origin));
sortTimeList(m_endTimes);
endListChanged(eventTime);
}
inline SMILTime extractTimeFromVector(const SMILTimeWithOrigin* position)
{
return position->time();
}
SMILTime SVGSMILElement::findInstanceTime(BeginOrEnd beginOrEnd, SMILTime minimumTime, bool equalsMinimumOK) const
{
const Vector<SMILTimeWithOrigin>& list = beginOrEnd == Begin ? m_beginTimes : m_endTimes;
int sizeOfList = list.size();
if (!sizeOfList)
return beginOrEnd == Begin ? SMILTime::unresolved() : SMILTime::indefinite();
const SMILTimeWithOrigin* result = approximateBinarySearch<const SMILTimeWithOrigin, SMILTime>(list, sizeOfList, minimumTime, extractTimeFromVector);
int indexOfResult = result - list.begin();
ASSERT_WITH_SECURITY_IMPLICATION(indexOfResult < sizeOfList);
if (list[indexOfResult].time() < minimumTime && indexOfResult < sizeOfList - 1)
++indexOfResult;
const SMILTime& currentTime = list[indexOfResult].time();
// The special value "indefinite" does not yield an instance time in the begin list.
if (currentTime.isIndefinite() && beginOrEnd == Begin)
return SMILTime::unresolved();
if (currentTime < minimumTime)
return beginOrEnd == Begin ? SMILTime::unresolved() : SMILTime::indefinite();
if (currentTime > minimumTime)
return currentTime;
ASSERT(currentTime == minimumTime);
if (equalsMinimumOK)
return currentTime;
// If the equals is not accepted, return the next bigger item in the list.
SMILTime nextTime = currentTime;
while (indexOfResult < sizeOfList - 1) {
nextTime = list[indexOfResult + 1].time();
if (nextTime > minimumTime)
return nextTime;
++indexOfResult;
}
return beginOrEnd == Begin ? SMILTime::unresolved() : SMILTime::indefinite();
}
SMILTime SVGSMILElement::repeatingDuration() const
{
// Computing the active duration
// http://www.w3.org/TR/SMIL2/smil-timing.html#Timing-ComputingActiveDur
SMILTime repeatCount = this->repeatCount();
SMILTime repeatDur = this->repeatDur();
SMILTime simpleDuration = this->simpleDuration();
if (!simpleDuration || (repeatDur.isUnresolved() && repeatCount.isUnresolved()))
return simpleDuration;
SMILTime repeatCountDuration = simpleDuration * repeatCount;
return std::min(repeatCountDuration, std::min(repeatDur, SMILTime::indefinite()));
}
SMILTime SVGSMILElement::resolveActiveEnd(SMILTime resolvedBegin, SMILTime resolvedEnd) const
{
// Computing the active duration
// http://www.w3.org/TR/SMIL2/smil-timing.html#Timing-ComputingActiveDur
SMILTime preliminaryActiveDuration;
if (!resolvedEnd.isUnresolved() && dur().isUnresolved() && repeatDur().isUnresolved() && repeatCount().isUnresolved())
preliminaryActiveDuration = resolvedEnd - resolvedBegin;
else if (!resolvedEnd.isFinite())
preliminaryActiveDuration = repeatingDuration();
else
preliminaryActiveDuration = std::min(repeatingDuration(), resolvedEnd - resolvedBegin);
SMILTime minValue = this->minValue();
SMILTime maxValue = this->maxValue();
if (minValue > maxValue) {
// Ignore both.
// http://www.w3.org/TR/2001/REC-smil-animation-20010904/#MinMax
minValue = 0;
maxValue = SMILTime::indefinite();
}
return resolvedBegin + std::min(maxValue, std::max(minValue, preliminaryActiveDuration));
}
void SVGSMILElement::resolveInterval(bool first, SMILTime& beginResult, SMILTime& endResult) const
{
// See the pseudocode in http://www.w3.org/TR/SMIL3/smil-timing.html#q90.
SMILTime beginAfter = first ? -std::numeric_limits<double>::infinity() : m_intervalEnd;
SMILTime lastIntervalTempEnd = std::numeric_limits<double>::infinity();
while (true) {
bool equalsMinimumOK = !first || m_intervalEnd > m_intervalBegin;
SMILTime tempBegin = findInstanceTime(Begin, beginAfter, equalsMinimumOK);
if (tempBegin.isUnresolved())
break;
SMILTime tempEnd;
if (m_endTimes.isEmpty())
tempEnd = resolveActiveEnd(tempBegin, SMILTime::indefinite());
else {
tempEnd = findInstanceTime(End, tempBegin, true);
if ((first && tempBegin == tempEnd && tempEnd == lastIntervalTempEnd) || (!first && tempEnd == m_intervalEnd))
tempEnd = findInstanceTime(End, tempBegin, false);
if (tempEnd.isUnresolved()) {
if (!m_endTimes.isEmpty() && !m_hasEndEventConditions)
break;
}
tempEnd = resolveActiveEnd(tempBegin, tempEnd);
}
if (!first || (tempEnd > 0 || (!tempBegin.value() && !tempEnd.value()))) {
beginResult = tempBegin;
endResult = tempEnd;
return;
}
beginAfter = tempEnd;
lastIntervalTempEnd = tempEnd;
}
beginResult = SMILTime::unresolved();
endResult = SMILTime::unresolved();
}
void SVGSMILElement::resolveFirstInterval()
{
SMILTime begin;
SMILTime end;
resolveInterval(true, begin, end);
ASSERT(!begin.isIndefinite());
if (!begin.isUnresolved() && (begin != m_intervalBegin || end != m_intervalEnd)) {
bool wasUnresolved = m_intervalBegin.isUnresolved();
m_intervalBegin = begin;
m_intervalEnd = end;
notifyDependentsIntervalChanged(wasUnresolved ? NewInterval : ExistingInterval);
m_nextProgressTime = std::min(m_nextProgressTime, m_intervalBegin);
if (m_timeContainer)
m_timeContainer->notifyIntervalsChanged();
}
}
void SVGSMILElement::resolveNextInterval(bool notifyDependents)
{
SMILTime begin;
SMILTime end;
resolveInterval(false, begin, end);
ASSERT(!begin.isIndefinite());
if (!begin.isUnresolved() && begin != m_intervalBegin) {
m_intervalBegin = begin;
m_intervalEnd = end;
if (notifyDependents)
notifyDependentsIntervalChanged(NewInterval);
m_nextProgressTime = std::min(m_nextProgressTime, m_intervalBegin);
}
}
SMILTime SVGSMILElement::nextProgressTime() const
{
return m_nextProgressTime;
}
void SVGSMILElement::beginListChanged(SMILTime eventTime)
{
if (m_isWaitingForFirstInterval)
resolveFirstInterval();
else {
SMILTime newBegin = findInstanceTime(Begin, eventTime, true);
if (newBegin.isFinite() && (m_intervalEnd <= eventTime || newBegin < m_intervalBegin)) {
// Begin time changed, re-resolve the interval.
SMILTime oldBegin = m_intervalBegin;
m_intervalEnd = eventTime;
resolveInterval(false, m_intervalBegin, m_intervalEnd);
ASSERT(!m_intervalBegin.isUnresolved());
if (m_intervalBegin != oldBegin) {
if (m_activeState == Active && m_intervalBegin > eventTime) {
m_activeState = determineActiveState(eventTime);
if (m_activeState != Active)
endedActiveInterval();
}
notifyDependentsIntervalChanged(ExistingInterval);
}
}
}
m_nextProgressTime = elapsed();
if (m_timeContainer)
m_timeContainer->notifyIntervalsChanged();
}
void SVGSMILElement::endListChanged(SMILTime)
{
SMILTime elapsed = this->elapsed();
if (m_isWaitingForFirstInterval)
resolveFirstInterval();
else if (elapsed < m_intervalEnd && m_intervalBegin.isFinite()) {
SMILTime newEnd = findInstanceTime(End, m_intervalBegin, false);
if (newEnd < m_intervalEnd) {
newEnd = resolveActiveEnd(m_intervalBegin, newEnd);
if (newEnd != m_intervalEnd) {
m_intervalEnd = newEnd;
notifyDependentsIntervalChanged(ExistingInterval);
}
}
}
m_nextProgressTime = elapsed;
if (m_timeContainer)
m_timeContainer->notifyIntervalsChanged();
}
void SVGSMILElement::checkRestart(SMILTime elapsed)
{
ASSERT(!m_isWaitingForFirstInterval);
ASSERT(elapsed >= m_intervalBegin);
Restart restart = this->restart();
if (restart == RestartNever)
return;
if (elapsed < m_intervalEnd) {
if (restart != RestartAlways)
return;
SMILTime nextBegin = findInstanceTime(Begin, m_intervalBegin, false);
if (nextBegin < m_intervalEnd) {
m_intervalEnd = nextBegin;
notifyDependentsIntervalChanged(ExistingInterval);
}
}
if (elapsed >= m_intervalEnd)
resolveNextInterval(true);
}
void SVGSMILElement::seekToIntervalCorrespondingToTime(SMILTime elapsed)
{
ASSERT(!m_isWaitingForFirstInterval);
ASSERT(elapsed >= m_intervalBegin);
// Manually seek from interval to interval, just as if the animation would run regulary.
while (true) {
// Figure out the next value in the begin time list after the current interval begin.
SMILTime nextBegin = findInstanceTime(Begin, m_intervalBegin, false);
// If the 'nextBegin' time is unresolved (eg. just one defined interval), we're done seeking.
if (nextBegin.isUnresolved())
return;
// If the 'nextBegin' time is larger than or equal to the current interval end time, we're done seeking.
// If the 'elapsed' time is smaller than the next begin interval time, we're done seeking.
if (nextBegin < m_intervalEnd && elapsed >= nextBegin) {
// End current interval, and start a new interval from the 'nextBegin' time.
m_intervalEnd = nextBegin;
resolveNextInterval(false);
continue;
}
// If the desired 'elapsed' time is past the current interval, advance to the next.
if (elapsed >= m_intervalEnd) {
resolveNextInterval(false);
continue;
}
return;
}
}
float SVGSMILElement::calculateAnimationPercentAndRepeat(SMILTime elapsed, unsigned& repeat) const
{
SMILTime simpleDuration = this->simpleDuration();
repeat = 0;
if (simpleDuration.isIndefinite()) {
repeat = 0;
return 0.f;
}
if (!simpleDuration) {
repeat = 0;
return 1.f;
}
ASSERT(m_intervalBegin.isFinite());
ASSERT(simpleDuration.isFinite());
SMILTime activeTime = elapsed - m_intervalBegin;
SMILTime repeatingDuration = this->repeatingDuration();
if (elapsed >= m_intervalEnd || activeTime > repeatingDuration) {
repeat = static_cast<unsigned>(repeatingDuration.value() / simpleDuration.value()) - 1;
double percent = (m_intervalEnd.value() - m_intervalBegin.value()) / simpleDuration.value();
percent = percent - floor(percent);
if (percent < std::numeric_limits<float>::epsilon() || 1 - percent < std::numeric_limits<float>::epsilon())
return 1.0f;
return narrowPrecisionToFloat(percent);
}
repeat = static_cast<unsigned>(activeTime.value() / simpleDuration.value());
SMILTime simpleTime = fmod(activeTime.value(), simpleDuration.value());
return narrowPrecisionToFloat(simpleTime.value() / simpleDuration.value());
}
SMILTime SVGSMILElement::calculateNextProgressTime(SMILTime elapsed) const
{
if (m_timeContainer && m_activeState == Active) {
// If duration is indefinite the value does not actually change over time. Same is true for <set>.
SMILTime simpleDuration = this->simpleDuration();
if (simpleDuration.isIndefinite() || hasTagName(SVGNames::setTag)) {
SMILTime repeatingDurationEnd = m_intervalBegin + repeatingDuration();
// We are supposed to do freeze semantics when repeating ends, even if the element is still active.
// Take care that we get a timer callback at that point.
if (elapsed < repeatingDurationEnd && repeatingDurationEnd < m_intervalEnd && repeatingDurationEnd.isFinite())
return repeatingDurationEnd;
return m_intervalEnd;
}
return elapsed + m_timeContainer->animationFrameDelay();
}
return m_intervalBegin >= elapsed ? m_intervalBegin : SMILTime::unresolved();
}
SVGSMILElement::ActiveState SVGSMILElement::determineActiveState(SMILTime elapsed) const
{
if (elapsed >= m_intervalBegin && elapsed < m_intervalEnd)
return Active;
return fill() == FillFreeze ? Frozen : Inactive;
}
bool SVGSMILElement::isContributing(SMILTime elapsed) const
{
// Animation does not contribute during the active time if it is past its repeating duration and has fill=remove.
return (m_activeState == Active && (fill() == FillFreeze || elapsed <= m_intervalBegin + repeatingDuration())) || m_activeState == Frozen;
}
bool SVGSMILElement::progress(SMILTime elapsed, SVGSMILElement* resultElement, bool seekToTime)
{
ASSERT(resultElement);
ASSERT(m_timeContainer);
ASSERT(m_isWaitingForFirstInterval || m_intervalBegin.isFinite());
if (!m_intervalBegin.isFinite()) {
ASSERT(m_activeState == Inactive);
m_nextProgressTime = SMILTime::unresolved();
return false;
}
if (elapsed < m_intervalBegin) {
ASSERT(m_activeState != Active);
if (m_activeState == Frozen) {
if (this == resultElement)
resetAnimatedType();
updateAnimation(m_lastPercent, m_lastRepeat, resultElement);
}
m_nextProgressTime = m_intervalBegin;
return false;
}
m_previousIntervalBegin = m_intervalBegin;
if (m_isWaitingForFirstInterval) {
m_isWaitingForFirstInterval = false;
resolveFirstInterval();
}
// This call may obtain a new interval -- never call calculateAnimationPercentAndRepeat() before!
if (seekToTime) {
seekToIntervalCorrespondingToTime(elapsed);
if (elapsed < m_intervalBegin) {
// elapsed is not within an interval.
m_nextProgressTime = m_intervalBegin;
return false;
}
}
unsigned repeat = 0;
float percent = calculateAnimationPercentAndRepeat(elapsed, repeat);
checkRestart(elapsed);
ActiveState oldActiveState = m_activeState;
m_activeState = determineActiveState(elapsed);
bool animationIsContributing = isContributing(elapsed);
// Only reset the animated type to the base value once for the lowest priority animation that animates and contributes to a particular element/attribute pair.
if (this == resultElement && animationIsContributing)
resetAnimatedType();
if (animationIsContributing) {
if (oldActiveState == Inactive)
startedActiveInterval();
updateAnimation(percent, repeat, resultElement);
m_lastPercent = percent;
m_lastRepeat = repeat;
}
if (oldActiveState == Active && m_activeState != Active) {
smilEndEventSender().dispatchEventSoon(*this);
endedActiveInterval();
if (m_activeState != Frozen)
clearAnimatedType(m_targetElement);
} else if (oldActiveState != Active && m_activeState == Active)
smilBeginEventSender().dispatchEventSoon(*this);
// Triggering all the pending events if the animation timeline is changed.
if (seekToTime) {
if (m_activeState == Inactive || m_activeState == Frozen)
smilEndEventSender().dispatchEventSoon(*this);
}
m_nextProgressTime = calculateNextProgressTime(elapsed);
return animationIsContributing;
}
void SVGSMILElement::notifyDependentsIntervalChanged(NewOrExistingInterval newOrExisting)
{
ASSERT(m_intervalBegin.isFinite());
static NeverDestroyed<HashSet<SVGSMILElement*>> loopBreaker;
if (loopBreaker.get().contains(this))
return;
loopBreaker.get().add(this);
for (auto& dependent : m_timeDependents) {
dependent->createInstanceTimesFromSyncbase(this, newOrExisting);
}
loopBreaker.get().remove(this);
}
void SVGSMILElement::createInstanceTimesFromSyncbase(SVGSMILElement* syncbase, NewOrExistingInterval)
{
// FIXME: To be really correct, this should handle updating exising interval by changing
// the associated times instead of creating new ones.
for (auto& condition : m_conditions) {
if (condition.m_type == Condition::Syncbase && condition.m_syncbase == syncbase) {
ASSERT(condition.m_name == "begin" || condition.m_name == "end");
// No nested time containers in SVG, no need for crazy time space conversions. Phew!
SMILTime time = 0;
if (condition.m_name == "begin")
time = syncbase->m_intervalBegin + condition.m_offset;
else
time = syncbase->m_intervalEnd + condition.m_offset;
if (!time.isFinite())
continue;
if (condition.m_beginOrEnd == Begin)
addBeginTime(elapsed(), time);
else
addEndTime(elapsed(), time);
}
}
}
void SVGSMILElement::addTimeDependent(SVGSMILElement* animation)
{
m_timeDependents.add(animation);
if (m_intervalBegin.isFinite())
animation->createInstanceTimesFromSyncbase(this, NewInterval);
}
void SVGSMILElement::removeTimeDependent(SVGSMILElement* animation)
{
m_timeDependents.remove(animation);
}
void SVGSMILElement::handleConditionEvent(Condition* condition)
{
SMILTime elapsed = this->elapsed();
if (condition->m_beginOrEnd == Begin)
addBeginTime(elapsed, elapsed + condition->m_offset);
else
addEndTime(elapsed, elapsed + condition->m_offset);
}
void SVGSMILElement::beginByLinkActivation()
{
SMILTime elapsed = this->elapsed();
addBeginTime(elapsed, elapsed);
}
void SVGSMILElement::endedActiveInterval()
{
clearTimesWithDynamicOrigins(m_beginTimes);
clearTimesWithDynamicOrigins(m_endTimes);
}
void SVGSMILElement::dispatchPendingEvent(SMILEventSender* eventSender)
{
ASSERT(eventSender == &smilBeginEventSender() || eventSender == &smilEndEventSender());
const AtomString& eventType = eventSender->eventType();
dispatchEvent(Event::create(eventType, Event::CanBubble::No, Event::IsCancelable::No));
}
}