/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2013 - Raw Material Software Ltd. Permission is granted to use this software under the terms of either: a) the GPL v2 (or any later version) b) the Affero GPL v3 Details of these licenses can be found at: www.gnu.org/licenses JUCE 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 General Public License for more details. ------------------------------------------------------------------------------ To release a closed-source product which uses JUCE, commercial licenses are available: visit www.juce.com for more information. ============================================================================== */ DrawablePath::DrawablePath() { } DrawablePath::DrawablePath (const DrawablePath& other) : DrawableShape (other) { if (other.relativePath != nullptr) setPath (*other.relativePath); else setPath (other.path); } DrawablePath::~DrawablePath() { } Drawable* DrawablePath::createCopy() const { return new DrawablePath (*this); } //============================================================================== void DrawablePath::setPath (const Path& newPath) { path = newPath; pathChanged(); } const Path& DrawablePath::getPath() const { return path; } const Path& DrawablePath::getStrokePath() const { return strokePath; } void DrawablePath::applyRelativePath (const RelativePointPath& newRelativePath, Expression::Scope* scope) { Path newPath; newRelativePath.createPath (newPath, scope); if (path != newPath) { path.swapWithPath (newPath); pathChanged(); } } //============================================================================== class DrawablePath::RelativePositioner : public RelativeCoordinatePositionerBase { public: RelativePositioner (DrawablePath& comp) : RelativeCoordinatePositionerBase (comp), owner (comp) { } bool registerCoordinates() { bool ok = true; jassert (owner.relativePath != nullptr); const RelativePointPath& path = *owner.relativePath; for (int i = 0; i < path.elements.size(); ++i) { RelativePointPath::ElementBase* const e = path.elements.getUnchecked(i); int numPoints; RelativePoint* const points = e->getControlPoints (numPoints); for (int j = numPoints; --j >= 0;) ok = addPoint (points[j]) && ok; } return ok; } void applyToComponentBounds() { jassert (owner.relativePath != nullptr); ComponentScope scope (getComponent()); owner.applyRelativePath (*owner.relativePath, &scope); } void applyNewBounds (const Rectangle&) { jassertfalse; // drawables can't be resized directly! } private: DrawablePath& owner; JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (RelativePositioner) }; void DrawablePath::setPath (const RelativePointPath& newRelativePath) { if (newRelativePath.containsAnyDynamicPoints()) { if (relativePath == nullptr || newRelativePath != *relativePath) { relativePath = new RelativePointPath (newRelativePath); RelativePositioner* const p = new RelativePositioner (*this); setPositioner (p); p->apply(); } } else { relativePath = nullptr; applyRelativePath (newRelativePath, nullptr); } } //============================================================================== const Identifier DrawablePath::valueTreeType ("Path"); const Identifier DrawablePath::ValueTreeWrapper::nonZeroWinding ("nonZeroWinding"); const Identifier DrawablePath::ValueTreeWrapper::point1 ("p1"); const Identifier DrawablePath::ValueTreeWrapper::point2 ("p2"); const Identifier DrawablePath::ValueTreeWrapper::point3 ("p3"); //============================================================================== DrawablePath::ValueTreeWrapper::ValueTreeWrapper (const ValueTree& state_) : FillAndStrokeState (state_) { jassert (state.hasType (valueTreeType)); } ValueTree DrawablePath::ValueTreeWrapper::getPathState() { return state.getOrCreateChildWithName (path, nullptr); } bool DrawablePath::ValueTreeWrapper::usesNonZeroWinding() const { return state [nonZeroWinding]; } void DrawablePath::ValueTreeWrapper::setUsesNonZeroWinding (bool b, UndoManager* undoManager) { state.setProperty (nonZeroWinding, b, undoManager); } void DrawablePath::ValueTreeWrapper::readFrom (const RelativePointPath& p, UndoManager* undoManager) { setUsesNonZeroWinding (p.usesNonZeroWinding, undoManager); ValueTree pathTree (getPathState()); pathTree.removeAllChildren (undoManager); for (int i = 0; i < p.elements.size(); ++i) pathTree.addChild (p.elements.getUnchecked(i)->createTree(), -1, undoManager); } void DrawablePath::ValueTreeWrapper::writeTo (RelativePointPath& p) const { p.usesNonZeroWinding = usesNonZeroWinding(); RelativePoint points[3]; const ValueTree pathTree (state.getChildWithName (path)); const int num = pathTree.getNumChildren(); for (int i = 0; i < num; ++i) { const Element e (pathTree.getChild(i)); const int numCps = e.getNumControlPoints(); for (int j = 0; j < numCps; ++j) points[j] = e.getControlPoint (j); RelativePointPath::ElementBase* newElement = nullptr; const Identifier t (e.getType()); if (t == Element::startSubPathElement) newElement = new RelativePointPath::StartSubPath (points[0]); else if (t == Element::closeSubPathElement) newElement = new RelativePointPath::CloseSubPath(); else if (t == Element::lineToElement) newElement = new RelativePointPath::LineTo (points[0]); else if (t == Element::quadraticToElement) newElement = new RelativePointPath::QuadraticTo (points[0], points[1]); else if (t == Element::cubicToElement) newElement = new RelativePointPath::CubicTo (points[0], points[1], points[2]); else jassertfalse; p.addElement (newElement); } } //============================================================================== const Identifier DrawablePath::ValueTreeWrapper::Element::mode ("mode"); const Identifier DrawablePath::ValueTreeWrapper::Element::startSubPathElement ("Move"); const Identifier DrawablePath::ValueTreeWrapper::Element::closeSubPathElement ("Close"); const Identifier DrawablePath::ValueTreeWrapper::Element::lineToElement ("Line"); const Identifier DrawablePath::ValueTreeWrapper::Element::quadraticToElement ("Quad"); const Identifier DrawablePath::ValueTreeWrapper::Element::cubicToElement ("Cubic"); const char* DrawablePath::ValueTreeWrapper::Element::cornerMode = "corner"; const char* DrawablePath::ValueTreeWrapper::Element::roundedMode = "round"; const char* DrawablePath::ValueTreeWrapper::Element::symmetricMode = "symm"; DrawablePath::ValueTreeWrapper::Element::Element (const ValueTree& state_) : state (state_) { } DrawablePath::ValueTreeWrapper::Element::~Element() { } DrawablePath::ValueTreeWrapper DrawablePath::ValueTreeWrapper::Element::getParent() const { return ValueTreeWrapper (state.getParent().getParent()); } DrawablePath::ValueTreeWrapper::Element DrawablePath::ValueTreeWrapper::Element::getPreviousElement() const { return Element (state.getSibling (-1)); } int DrawablePath::ValueTreeWrapper::Element::getNumControlPoints() const noexcept { const Identifier i (state.getType()); if (i == startSubPathElement || i == lineToElement) return 1; if (i == quadraticToElement) return 2; if (i == cubicToElement) return 3; return 0; } RelativePoint DrawablePath::ValueTreeWrapper::Element::getControlPoint (const int index) const { jassert (index >= 0 && index < getNumControlPoints()); return RelativePoint (state [index == 0 ? point1 : (index == 1 ? point2 : point3)].toString()); } Value DrawablePath::ValueTreeWrapper::Element::getControlPointValue (int index, UndoManager* undoManager) { jassert (index >= 0 && index < getNumControlPoints()); return state.getPropertyAsValue (index == 0 ? point1 : (index == 1 ? point2 : point3), undoManager); } void DrawablePath::ValueTreeWrapper::Element::setControlPoint (const int index, const RelativePoint& point, UndoManager* undoManager) { jassert (index >= 0 && index < getNumControlPoints()); state.setProperty (index == 0 ? point1 : (index == 1 ? point2 : point3), point.toString(), undoManager); } RelativePoint DrawablePath::ValueTreeWrapper::Element::getStartPoint() const { const Identifier i (state.getType()); if (i == startSubPathElement) return getControlPoint (0); jassert (i == lineToElement || i == quadraticToElement || i == cubicToElement || i == closeSubPathElement); return getPreviousElement().getEndPoint(); } RelativePoint DrawablePath::ValueTreeWrapper::Element::getEndPoint() const { const Identifier i (state.getType()); if (i == startSubPathElement || i == lineToElement) return getControlPoint (0); if (i == quadraticToElement) return getControlPoint (1); if (i == cubicToElement) return getControlPoint (2); jassert (i == closeSubPathElement); return RelativePoint(); } float DrawablePath::ValueTreeWrapper::Element::getLength (Expression::Scope* scope) const { const Identifier i (state.getType()); if (i == lineToElement || i == closeSubPathElement) return getEndPoint().resolve (scope).getDistanceFrom (getStartPoint().resolve (scope)); if (i == cubicToElement) { Path p; p.startNewSubPath (getStartPoint().resolve (scope)); p.cubicTo (getControlPoint (0).resolve (scope), getControlPoint (1).resolve (scope), getControlPoint (2).resolve (scope)); return p.getLength(); } if (i == quadraticToElement) { Path p; p.startNewSubPath (getStartPoint().resolve (scope)); p.quadraticTo (getControlPoint (0).resolve (scope), getControlPoint (1).resolve (scope)); return p.getLength(); } jassert (i == startSubPathElement); return 0; } String DrawablePath::ValueTreeWrapper::Element::getModeOfEndPoint() const { return state [mode].toString(); } void DrawablePath::ValueTreeWrapper::Element::setModeOfEndPoint (const String& newMode, UndoManager* undoManager) { if (state.hasType (cubicToElement)) state.setProperty (mode, newMode, undoManager); } void DrawablePath::ValueTreeWrapper::Element::convertToLine (UndoManager* undoManager) { const Identifier i (state.getType()); if (i == quadraticToElement || i == cubicToElement) { ValueTree newState (lineToElement); Element e (newState); e.setControlPoint (0, getEndPoint(), undoManager); state = newState; } } void DrawablePath::ValueTreeWrapper::Element::convertToCubic (Expression::Scope* scope, UndoManager* undoManager) { const Identifier i (state.getType()); if (i == lineToElement || i == quadraticToElement) { ValueTree newState (cubicToElement); Element e (newState); const RelativePoint start (getStartPoint()); const RelativePoint end (getEndPoint()); const Point startResolved (start.resolve (scope)); const Point endResolved (end.resolve (scope)); e.setControlPoint (0, startResolved + (endResolved - startResolved) * 0.3f, undoManager); e.setControlPoint (1, startResolved + (endResolved - startResolved) * 0.7f, undoManager); e.setControlPoint (2, end, undoManager); state = newState; } } void DrawablePath::ValueTreeWrapper::Element::convertToPathBreak (UndoManager* undoManager) { const Identifier i (state.getType()); if (i != startSubPathElement) { ValueTree newState (startSubPathElement); Element e (newState); e.setControlPoint (0, getEndPoint(), undoManager); state = newState; } } namespace DrawablePathHelpers { static Point findCubicSubdivisionPoint (float proportion, const Point points[4]) { const Point mid1 (points[0] + (points[1] - points[0]) * proportion), mid2 (points[1] + (points[2] - points[1]) * proportion), mid3 (points[2] + (points[3] - points[2]) * proportion); const Point newCp1 (mid1 + (mid2 - mid1) * proportion), newCp2 (mid2 + (mid3 - mid2) * proportion); return newCp1 + (newCp2 - newCp1) * proportion; } static Point findQuadraticSubdivisionPoint (float proportion, const Point points[3]) { const Point mid1 (points[0] + (points[1] - points[0]) * proportion), mid2 (points[1] + (points[2] - points[1]) * proportion); return mid1 + (mid2 - mid1) * proportion; } } float DrawablePath::ValueTreeWrapper::Element::findProportionAlongLine (Point targetPoint, Expression::Scope* scope) const { using namespace DrawablePathHelpers; const Identifier pointType (state.getType()); float bestProp = 0; if (pointType == cubicToElement) { RelativePoint rp1 (getStartPoint()), rp2 (getControlPoint (0)), rp3 (getControlPoint (1)), rp4 (getEndPoint()); const Point points[] = { rp1.resolve (scope), rp2.resolve (scope), rp3.resolve (scope), rp4.resolve (scope) }; float bestDistance = std::numeric_limits::max(); for (int i = 110; --i >= 0;) { float prop = i > 10 ? ((i - 10) / 100.0f) : (bestProp + ((i - 5) / 1000.0f)); const Point centre (findCubicSubdivisionPoint (prop, points)); const float distance = centre.getDistanceFrom (targetPoint); if (distance < bestDistance) { bestProp = prop; bestDistance = distance; } } } else if (pointType == quadraticToElement) { RelativePoint rp1 (getStartPoint()), rp2 (getControlPoint (0)), rp3 (getEndPoint()); const Point points[] = { rp1.resolve (scope), rp2.resolve (scope), rp3.resolve (scope) }; float bestDistance = std::numeric_limits::max(); for (int i = 110; --i >= 0;) { float prop = i > 10 ? ((i - 10) / 100.0f) : (bestProp + ((i - 5) / 1000.0f)); const Point centre (findQuadraticSubdivisionPoint ((float) prop, points)); const float distance = centre.getDistanceFrom (targetPoint); if (distance < bestDistance) { bestProp = prop; bestDistance = distance; } } } else if (pointType == lineToElement) { RelativePoint rp1 (getStartPoint()), rp2 (getEndPoint()); const Line line (rp1.resolve (scope), rp2.resolve (scope)); bestProp = line.findNearestProportionalPositionTo (targetPoint); } return bestProp; } ValueTree DrawablePath::ValueTreeWrapper::Element::insertPoint (Point targetPoint, Expression::Scope* scope, UndoManager* undoManager) { ValueTree newTree; const Identifier pointType (state.getType()); if (pointType == cubicToElement) { float bestProp = findProportionAlongLine (targetPoint, scope); RelativePoint rp1 (getStartPoint()), rp2 (getControlPoint (0)), rp3 (getControlPoint (1)), rp4 (getEndPoint()); const Point points[] = { rp1.resolve (scope), rp2.resolve (scope), rp3.resolve (scope), rp4.resolve (scope) }; const Point mid1 (points[0] + (points[1] - points[0]) * bestProp), mid2 (points[1] + (points[2] - points[1]) * bestProp), mid3 (points[2] + (points[3] - points[2]) * bestProp); const Point newCp1 (mid1 + (mid2 - mid1) * bestProp), newCp2 (mid2 + (mid3 - mid2) * bestProp); const Point newCentre (newCp1 + (newCp2 - newCp1) * bestProp); setControlPoint (0, mid1, undoManager); setControlPoint (1, newCp1, undoManager); setControlPoint (2, newCentre, undoManager); setModeOfEndPoint (roundedMode, undoManager); Element newElement (newTree = ValueTree (cubicToElement)); newElement.setControlPoint (0, newCp2, nullptr); newElement.setControlPoint (1, mid3, nullptr); newElement.setControlPoint (2, rp4, nullptr); state.getParent().addChild (newTree, state.getParent().indexOf (state) + 1, undoManager); } else if (pointType == quadraticToElement) { float bestProp = findProportionAlongLine (targetPoint, scope); RelativePoint rp1 (getStartPoint()), rp2 (getControlPoint (0)), rp3 (getEndPoint()); const Point points[] = { rp1.resolve (scope), rp2.resolve (scope), rp3.resolve (scope) }; const Point mid1 (points[0] + (points[1] - points[0]) * bestProp), mid2 (points[1] + (points[2] - points[1]) * bestProp); const Point newCentre (mid1 + (mid2 - mid1) * bestProp); setControlPoint (0, mid1, undoManager); setControlPoint (1, newCentre, undoManager); setModeOfEndPoint (roundedMode, undoManager); Element newElement (newTree = ValueTree (quadraticToElement)); newElement.setControlPoint (0, mid2, nullptr); newElement.setControlPoint (1, rp3, nullptr); state.getParent().addChild (newTree, state.getParent().indexOf (state) + 1, undoManager); } else if (pointType == lineToElement) { RelativePoint rp1 (getStartPoint()), rp2 (getEndPoint()); const Line line (rp1.resolve (scope), rp2.resolve (scope)); const Point newPoint (line.findNearestPointTo (targetPoint)); setControlPoint (0, newPoint, undoManager); Element newElement (newTree = ValueTree (lineToElement)); newElement.setControlPoint (0, rp2, nullptr); state.getParent().addChild (newTree, state.getParent().indexOf (state) + 1, undoManager); } else if (pointType == closeSubPathElement) { } return newTree; } void DrawablePath::ValueTreeWrapper::Element::removePoint (UndoManager* undoManager) { state.getParent().removeChild (state, undoManager); } //============================================================================== void DrawablePath::refreshFromValueTree (const ValueTree& tree, ComponentBuilder& builder) { ValueTreeWrapper v (tree); setComponentID (v.getID()); refreshFillTypes (v, builder.getImageProvider()); setStrokeType (v.getStrokeType()); RelativePointPath newRelativePath; v.writeTo (newRelativePath); setPath (newRelativePath); } ValueTree DrawablePath::createValueTree (ComponentBuilder::ImageProvider* imageProvider) const { ValueTree tree (valueTreeType); ValueTreeWrapper v (tree); v.setID (getComponentID()); writeTo (v, imageProvider, nullptr); if (relativePath != nullptr) v.readFrom (*relativePath, nullptr); else v.readFrom (RelativePointPath (path), nullptr); return tree; }