bool SVGLinearGradientElement::collectGradientAttributes(LinearGradientAttributes& attributes)
{
if (!renderer())
return false;
HashSet<SVGGradientElement*> processedGradients;
SVGGradientElement* current = this;
setGradientAttributes(current, attributes);
processedGradients.add(current);
while (true) {
// Respect xlink:href, take attributes from referenced element
Node* refNode = SVGURIReference::targetElementFromIRIString(current->href()->currentValue()->value(), treeScope());
if (refNode && isSVGGradientElement(*refNode)) {
current = toSVGGradientElement(refNode);
// Cycle detection
if (processedGradients.contains(current))
return true;
if (!current->renderer())
return false;
setGradientAttributes(current, attributes, isSVGLinearGradientElement(*current));
processedGradients.add(current);
} else {
return true;
}
}
ASSERT_NOT_REACHED();
return false;
}
bool SVGLinearGradientElement::collectGradientAttributes(LinearGradientAttributes& attributes)
{
if (!renderer())
return false;
HashSet<SVGGradientElement*> processedGradients;
SVGGradientElement* current = this;
setGradientAttributes(*current, attributes);
processedGradients.add(current);
while (true) {
// Respect xlink:href, take attributes from referenced element
Node* refNode = SVGURIReference::targetElementFromIRIString(current->href(), document());
if (is<SVGGradientElement>(refNode)) {
current = downcast<SVGGradientElement>(refNode);
// Cycle detection
if (processedGradients.contains(current))
return true;
if (!current->renderer())
return false;
setGradientAttributes(*current, attributes, current->hasTagName(SVGNames::linearGradientTag));
processedGradients.add(current);
} else
return true;
}
ASSERT_NOT_REACHED();
return false;
}
LinearGradientAttributes SVGLinearGradientElement::collectGradientProperties()
{
LinearGradientAttributes attributes;
HashSet<SVGGradientElement*> processedGradients;
bool isLinear = true;
SVGGradientElement* current = this;
while (current) {
if (!attributes.hasSpreadMethod() && current->hasAttribute(SVGNames::spreadMethodAttr))
attributes.setSpreadMethod((GradientSpreadMethod) current->spreadMethod());
if (!attributes.hasBoundingBoxMode() && current->hasAttribute(SVGNames::gradientUnitsAttr))
attributes.setBoundingBoxMode(current->gradientUnits() == SVGUnitTypes::SVG_UNIT_TYPE_OBJECTBOUNDINGBOX);
if (!attributes.hasGradientTransform() && current->hasAttribute(SVGNames::gradientTransformAttr))
attributes.setGradientTransform(current->gradientTransform()->consolidate().matrix());
if (!attributes.hasStops()) {
const Vector<Gradient::ColorStop>& stops(current->buildStops());
if (!stops.isEmpty())
attributes.setStops(stops);
}
if (isLinear) {
SVGLinearGradientElement* linear = static_cast<SVGLinearGradientElement*>(current);
if (!attributes.hasX1() && current->hasAttribute(SVGNames::x1Attr))
attributes.setX1(linear->x1());
if (!attributes.hasY1() && current->hasAttribute(SVGNames::y1Attr))
attributes.setY1(linear->y1());
if (!attributes.hasX2() && current->hasAttribute(SVGNames::x2Attr))
attributes.setX2(linear->x2());
if (!attributes.hasY2() && current->hasAttribute(SVGNames::y2Attr))
attributes.setY2(linear->y2());
}
processedGradients.add(current);
// Respect xlink:href, take attributes from referenced element
Node* refNode = ownerDocument()->getElementById(SVGURIReference::getTarget(current->href()));
if (refNode && (refNode->hasTagName(SVGNames::linearGradientTag) || refNode->hasTagName(SVGNames::radialGradientTag))) {
current = static_cast<SVGGradientElement*>(refNode);
// Cycle detection
if (processedGradients.contains(current))
return LinearGradientAttributes();
isLinear = current->hasTagName(SVGNames::linearGradientTag);
} else
current = 0;
}
return attributes;
}
bool SVGRadialGradientElement::collectGradientAttributes(RadialGradientAttributes& attributes)
{
if (!renderer())
return false;
WillBeHeapHashSet<RawPtrWillBeMember<SVGGradientElement> > processedGradients;
SVGGradientElement* current = this;
setGradientAttributes(current, attributes);
processedGradients.add(current);
while (true) {
// Respect xlink:href, take attributes from referenced element
Node* refNode = SVGURIReference::targetElementFromIRIString(current->href()->currentValue()->value(), treeScope());
if (refNode && isSVGGradientElement(*refNode)) {
current = toSVGGradientElement(refNode);
// Cycle detection
if (processedGradients.contains(current))
break;
if (!current->renderer())
return false;
setGradientAttributes(current, attributes, isSVGRadialGradientElement(*current));
processedGradients.add(current);
} else {
break;
}
}
// Handle default values for fx/fy
if (!attributes.hasFx())
attributes.setFx(attributes.cx());
if (!attributes.hasFy())
attributes.setFy(attributes.cy());
return true;
}
bool SVGRadialGradientElement::collectGradientAttributes(RadialGradientAttributes& attributes)
{
if (!renderer())
return false;
HashSet<SVGGradientElement*> processedGradients;
SVGGradientElement* current = this;
setGradientAttributes(*current, attributes);
processedGradients.add(current);
while (true) {
// Respect xlink:href, take attributes from referenced element
Node* refNode = SVGURIReference::targetElementFromIRIString(current->href(), document());
if (is<SVGGradientElement>(refNode)) {
current = downcast<SVGGradientElement>(refNode);
// Cycle detection
if (processedGradients.contains(current))
break;
if (!current->renderer())
return false;
setGradientAttributes(*current, attributes, current->hasTagName(SVGNames::radialGradientTag));
processedGradients.add(current);
} else
break;
}
// Handle default values for fx/fy
if (!attributes.hasFx())
attributes.setFx(attributes.cx());
if (!attributes.hasFy())
attributes.setFy(attributes.cy());
return true;
}