/**
* Finds a control point index. Returns -1 if no control point could be found. FIXME - Move this
* to BezierPath
*/
public int findNode(Point2D.Double p) {
BezierPath tp = path;
for (int i = 0; i < tp.size(); i++) {
BezierPath.Node p2 = tp.get(i);
if (p2.x[0] == p.x && p2.y[0] == p.y) {
return i;
}
}
return -1;
}
@Override
public <T> void set(AttributeKey<T> key, T newValue) {
if (key == PATH_CLOSED) {
path.setClosed((Boolean) newValue);
} else if (key == WINDING_RULE) {
path.setWindingRule(
newValue == AttributeKeys.WindingRule.EVEN_ODD
? Path2D.Double.WIND_EVEN_ODD
: Path2D.Double.WIND_NON_ZERO);
}
super.set(key, newValue);
invalidate();
}
public Point2D.Double chop(Point2D.Double p) {
if (isClosed()) {
double grow = AttributeKeys.getPerpendicularHitGrowth(this);
if (grow == 0d) {
return path.chop(p);
} else {
GrowStroke gs =
new GrowStroke(grow, AttributeKeys.getStrokeTotalWidth(this) * get(STROKE_MITER_LIMIT));
return Geom.chop(gs.createStrokedShape(path), p);
}
} else {
return path.chop(p);
}
}
/**
* Returns a path which is cappedPath at the ends, to prevent it from drawing under the end caps.
*/
protected BezierPath getCappedPath() {
if (cappedPath == null) {
cappedPath = path.clone();
if (isClosed()) {
cappedPath.setClosed(true);
} else {
if (cappedPath.size() > 1) {
if (get(START_DECORATION) != null) {
BezierPath.Node p0 = cappedPath.get(0);
BezierPath.Node p1 = cappedPath.get(1);
Point2D.Double pp;
if ((p0.getMask() & BezierPath.C2_MASK) != 0) {
pp = p0.getControlPoint(2);
} else if ((p1.getMask() & BezierPath.C1_MASK) != 0) {
pp = p1.getControlPoint(1);
} else {
pp = p1.getControlPoint(0);
}
double radius = get(START_DECORATION).getDecorationRadius(this);
double lineLength = Geom.length(p0.getControlPoint(0), pp);
cappedPath.set(
0, 0, Geom.cap(pp, p0.getControlPoint(0), -Math.min(radius, lineLength)));
}
if (get(END_DECORATION) != null) {
BezierPath.Node p0 = cappedPath.get(cappedPath.size() - 1);
BezierPath.Node p1 = cappedPath.get(cappedPath.size() - 2);
Point2D.Double pp;
if ((p0.getMask() & BezierPath.C1_MASK) != 0) {
pp = p0.getControlPoint(1);
} else if ((p1.getMask() & BezierPath.C2_MASK) != 0) {
pp = p1.getControlPoint(2);
} else {
pp = p1.getControlPoint(0);
}
double radius = get(END_DECORATION).getDecorationRadius(this);
double lineLength = Geom.length(p0.getControlPoint(0), pp);
cappedPath.set(
cappedPath.size() - 1,
0,
Geom.cap(pp, p0.getControlPoint(0), -Math.min(radius, lineLength)));
}
cappedPath.invalidatePath();
}
}
}
return cappedPath;
}
/** Sets the point coordinate of control point 0 at the specified node. */
public void setPoint(int index, Point2D.Double p) {
BezierPath.Node node = path.get(index);
double dx = p.x - node.x[0];
double dy = p.y - node.y[0];
for (int i = 0; i < node.x.length; i++) {
node.x[i] += dx;
node.y[i] += dy;
}
invalidate();
}
@Override
public boolean contains(Point2D.Double p) {
double tolerance = Math.max(2f, AttributeKeys.getStrokeTotalWidth(this) / 2d);
if (isClosed() || get(FILL_COLOR) != null && get(UNCLOSED_PATH_FILLED)) {
if (path.contains(p)) {
return true;
}
double grow = AttributeKeys.getPerpendicularHitGrowth(this) * 2d;
GrowStroke gs =
new GrowStroke(grow, AttributeKeys.getStrokeTotalWidth(this) * get(STROKE_MITER_LIMIT));
if (gs.createStrokedShape(path).contains(p)) {
return true;
} else {
if (isClosed()) {
return false;
}
}
}
if (!isClosed()) {
if (getCappedPath().outlineContains(p, tolerance)) {
return true;
}
if (get(START_DECORATION) != null) {
BezierPath cp = getCappedPath();
Point2D.Double p1 = path.get(0, 0);
Point2D.Double p2 = cp.get(0, 0);
// FIXME - Check here, if caps path contains the point
if (Geom.lineContainsPoint(p1.x, p1.y, p2.x, p2.y, p.x, p.y, tolerance)) {
return true;
}
}
if (get(END_DECORATION) != null) {
BezierPath cp = getCappedPath();
Point2D.Double p1 = path.get(path.size() - 1, 0);
Point2D.Double p2 = cp.get(path.size() - 1, 0);
// FIXME - Check here, if caps path contains the point
if (Geom.lineContainsPoint(p1.x, p1.y, p2.x, p2.y, p.x, p.y, tolerance)) {
return true;
}
}
}
return false;
}
protected void readPoints(DOMInput in) throws IOException {
path.clear();
in.openElement("points");
setClosed(in.getAttribute("closed", false));
for (int i = 0, n = in.getElementCount("p"); i < n; i++) {
in.openElement("p", i);
BezierPath.Node node =
new BezierPath.Node(
in.getAttribute("mask", 0),
in.getAttribute("x", 0d),
in.getAttribute("y", 0d),
in.getAttribute("c1x", in.getAttribute("x", 0d)),
in.getAttribute("c1y", in.getAttribute("y", 0d)),
in.getAttribute("c2x", in.getAttribute("x", 0d)),
in.getAttribute("c2y", in.getAttribute("y", 0d)));
node.keepColinear = in.getAttribute("colinear", true);
path.add(node);
path.invalidatePath();
in.closeElement();
}
in.closeElement();
}
@Override
public Collection<Handle> createHandles(int detailLevel) {
LinkedList<Handle> handles = new LinkedList<Handle>();
switch (detailLevel % 2) {
case -1: // Mouse hover handles
handles.add(new BezierOutlineHandle(this, true));
break;
case 0:
handles.add(new BezierOutlineHandle(this));
for (int i = 0, n = path.size(); i < n; i++) {
handles.add(new BezierNodeHandle(this, i));
}
break;
case 1:
TransformHandleKit.addTransformHandles(this, handles);
handles.add(new BezierScaleHandle(this));
break;
}
return handles;
}
public Point2D.Double getCenter() {
return path.getCenter();
}
@Override
public Object getTransformRestoreData() {
return path.clone();
}
/** Returns a clone of the bezier path of this figure. */
public BezierPath getBezierPath() {
return path.clone();
}
/** Gets the node count. */
public int getNodeCount() {
return path.size();
}
@Override
public void restoreTransformTo(Object geometry) {
path.setTo((BezierPath) geometry);
}
@Override
public void invalidate() {
super.invalidate();
path.invalidatePath();
cappedPath = null;
}
/** Removes the Point2D.Double at the specified index. */
protected void removeAllNodes() {
path.clear();
}
public Point2D.Double getOutermostPoint() {
return path.get(path.indexOfOutermostNode()).getControlPoint(0);
}
/**
* Splits the segment at the given Point2D.Double if a segment was hit.
*
* @return the index of the segment or -1 if no segment was hit.
*/
public int splitSegment(Point2D.Double split, float tolerance) {
return path.splitSegment(split, tolerance);
}
/** Gets the point coordinate of a control point. */
public Point2D.Double getPoint(int index, int coord) {
return path.get(index).getControlPoint(coord);
}
public static String toPathData(BezierPath path) {
StringBuilder buf = new StringBuilder();
if (path.size() == 0) {
// nothing to do
} else if (path.size() == 1) {
BezierPath.Node current = path.get(0);
buf.append("M ");
buf.append(current.x[0]);
buf.append(' ');
buf.append(current.y[0]);
buf.append(" L ");
buf.append(current.x[0]);
buf.append(' ');
buf.append(current.y[0] + 1);
} else {
BezierPath.Node previous;
BezierPath.Node current;
previous = current = path.get(0);
buf.append("M ");
buf.append(current.x[0]);
buf.append(' ');
buf.append(current.y[0]);
for (int i = 1, n = path.size(); i < n; i++) {
previous = current;
current = path.get(i);
if ((previous.mask & BezierPath.C2_MASK) == 0) {
if ((current.mask & BezierPath.C1_MASK) == 0) {
buf.append(" L ");
buf.append(current.x[0]);
buf.append(' ');
buf.append(current.y[0]);
} else {
buf.append(" Q ");
buf.append(current.x[1]);
buf.append(' ');
buf.append(current.y[1]);
buf.append(' ');
buf.append(current.x[0]);
buf.append(' ');
buf.append(current.y[0]);
}
} else {
if ((current.mask & BezierPath.C1_MASK) == 0) {
buf.append(" Q ");
buf.append(current.x[2]);
buf.append(' ');
buf.append(current.y[2]);
buf.append(' ');
buf.append(current.x[0]);
buf.append(' ');
buf.append(current.y[0]);
} else {
buf.append(" C ");
buf.append(previous.x[2]);
buf.append(' ');
buf.append(previous.y[2]);
buf.append(' ');
buf.append(current.x[1]);
buf.append(' ');
buf.append(current.y[1]);
buf.append(' ');
buf.append(current.x[0]);
buf.append(' ');
buf.append(current.y[0]);
}
}
}
if (path.isClosed()) {
if (path.size() > 1) {
previous = path.get(path.size() - 1);
current = path.get(0);
if ((previous.mask & BezierPath.C2_MASK) == 0) {
if ((current.mask & BezierPath.C1_MASK) == 0) {
buf.append(" L ");
buf.append(current.x[0]);
buf.append(' ');
buf.append(current.y[0]);
} else {
buf.append(" Q ");
buf.append(current.x[1]);
buf.append(' ');
buf.append(current.y[1]);
buf.append(' ');
buf.append(current.x[0]);
buf.append(' ');
buf.append(current.y[0]);
}
} else {
if ((current.mask & BezierPath.C1_MASK) == 0) {
buf.append(" Q ");
buf.append(previous.x[2]);
buf.append(' ');
buf.append(previous.y[2]);
buf.append(' ');
buf.append(current.x[0]);
buf.append(' ');
buf.append(current.y[0]);
} else {
buf.append(" C ");
buf.append(previous.x[2]);
buf.append(' ');
buf.append(previous.y[2]);
buf.append(' ');
buf.append(current.x[1]);
buf.append(' ');
buf.append(current.y[1]);
buf.append(' ');
buf.append(current.x[0]);
buf.append(' ');
buf.append(current.y[0]);
}
}
}
buf.append(" Z");
}
}
return buf.toString();
}
/**
* Convenience method for getting the point coordinate of the first control point of the specified
* node.
*/
public Point2D.Double getPoint(int index) {
return path.get(index).getControlPoint(0);
}
/** Gets a control point. */
public BezierPath.Node getNode(int index) {
return (BezierPath.Node) path.get(index).clone();
}
/** Sets a control point. */
public void setNode(int index, BezierPath.Node p) {
path.set(index, p);
invalidate();
}
/** Adds a node to the list of points. */
public void addNode(final int index, BezierPath.Node p) {
path.add(index, p);
invalidate();
}
public Point2D.Double getPointOnPath(float relative, double flatness) {
return path.getPointOnPath(relative, flatness);
}
/**
* Joins two segments into one if the given Point2D.Double hits a node of the polyline.
*
* @return true if the two segments were joined.
*/
public int joinSegments(Point2D.Double join, float tolerance) {
return path.joinSegments(join, tolerance);
}
public void setBezierPath(BezierPath newValue) {
path = newValue.clone();
this.setClosed(newValue.isClosed());
}
/** Removes the Node at the specified index. */
public BezierPath.Node removeNode(int index) {
return path.remove(index);
}
@Override
public void transform(AffineTransform tx) {
path.transform(tx);
invalidate();
}
public static List<BezierPath> fromPathData(String str) throws IOException {
LinkedList<BezierPath> paths = new LinkedList<BezierPath>();
BezierPath path = null;
Point2D.Double p = new Point2D.Double();
Point2D.Double c1 = new Point2D.Double();
Point2D.Double c2 = new Point2D.Double();
StreamTokenizer tt = new StreamTokenizer(new StringReader(str));
tt.resetSyntax();
tt.parseNumbers();
tt.whitespaceChars(0, ' ');
tt.whitespaceChars(',', ',');
char nextCommand = 'M';
char command = 'M';
while (tt.nextToken() != StreamTokenizer.TT_EOF) {
if (tt.ttype > 0) {
command = (char) tt.ttype;
} else {
command = nextCommand;
tt.pushBack();
}
BezierPath.Node node;
switch (command) {
// moveto
case 'M':
if (path != null) {
paths.add(path);
}
path = new BezierPath();
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y = tt.nval;
path.moveTo(p.x, p.y);
nextCommand = 'L';
break;
case 'm':
if (path != null) {
paths.add(path);
}
path = new BezierPath();
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x += tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y += tt.nval;
path.moveTo(p.x, p.y);
nextCommand = 'l';
// close path
break;
case 'Z':
case 'z':
p.x = path.get(0).x[0];
p.y = path.get(0).y[0];
path.setClosed(true);
// lineto
break;
case 'L':
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y = tt.nval;
path.lineTo(p.x, p.y);
nextCommand = 'L';
break;
case 'l':
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x += tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y += tt.nval;
path.lineTo(p.x, p.y);
nextCommand = 'l';
break;
case 'H':
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x = tt.nval;
path.lineTo(p.x, p.y);
nextCommand = 'H';
break;
case 'h':
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x += tt.nval;
path.lineTo(p.x, p.y);
nextCommand = 'h';
break;
case 'V':
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y = tt.nval;
path.lineTo(p.x, p.y);
nextCommand = 'V';
break;
case 'v':
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y += tt.nval;
path.lineTo(p.x, p.y);
nextCommand = 'v';
// curveto
break;
case 'C':
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c1.x = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c1.y = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c2.x = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c2.y = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y = tt.nval;
path.curveTo(c1.x, c1.y, c2.x, c2.y, p.x, p.y);
nextCommand = 'C';
break;
case 'c':
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c1.x = p.x + tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c1.y = p.y + tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c2.x = p.x + tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c2.y = p.y + tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x += tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y += tt.nval;
path.curveTo(c1.x, c1.y, c2.x, c2.y, p.x, p.y);
nextCommand = 'c';
break;
case 'S':
node = path.get(path.size() - 1);
c1.x = node.x[0] * 2d - node.x[1];
c1.y = node.y[0] * 2d - node.y[1];
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c2.x = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c2.y = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y = tt.nval;
path.curveTo(c1.x, c1.y, c2.x, c2.y, p.x, p.y);
nextCommand = 'S';
break;
case 's':
node = path.get(path.size() - 1);
c1.x = node.x[0] * 2d - node.x[1];
c1.y = node.y[0] * 2d - node.y[1];
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c2.x = p.x + tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c2.y = p.y + tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x += tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y += tt.nval;
path.curveTo(c1.x, c1.y, c2.x, c2.y, p.x, p.y);
nextCommand = 's';
// quadto
break;
case 'Q':
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c1.x = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c1.y = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y = tt.nval;
path.quadTo(c1.x, c1.y, p.x, p.y);
nextCommand = 'Q';
break;
case 'q':
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c1.x = p.x + tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
c1.y = p.y + tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x += tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y += tt.nval;
path.quadTo(c1.x, c1.y, p.x, p.y);
nextCommand = 'q';
break;
case 'T':
node = path.get(path.size() - 1);
c1.x = node.x[0] * 2d - node.x[1];
c1.y = node.y[0] * 2d - node.y[1];
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x = tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y = tt.nval;
path.quadTo(c1.x, c1.y, p.x, p.y);
nextCommand = 'T';
break;
case 't':
node = path.get(path.size() - 1);
c1.x = node.x[0] * 2d - node.x[1];
c1.y = node.y[0] * 2d - node.y[1];
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.x += tt.nval;
if (tt.nextToken() != StreamTokenizer.TT_NUMBER) throw new IOException("Number expected");
p.y += tt.nval;
path.quadTo(c1.x, c1.y, p.x, p.y);
nextCommand = 's';
break;
default:
throw new IOException("Illegal command: " + command);
}
}
if (path != null) {
paths.add(path);
}
return paths;
}
/** Sets the point coordinate of a control point. */
public void setPoint(int index, int coord, Point2D.Double p) {
BezierPath.Node cp = new BezierPath.Node(path.get(index));
cp.setControlPoint(coord, p);
setNode(index, cp);
}