ij.gui.Roi (2D Regions Of Interest) implemented in terms of java.awt.Shape.
* A ShapeRoi is constructed from a ij.gui.Roi object, or as a result of logical operators
* (i.e., union, intersection, exclusive or, and subtraction) provided by this class. These operators use the package
* java.awt.geom as a backend. true.
*/
private static final int MAXPOLY = 10; // I hate arbitrary values !!!!
private static final int OR=0, AND=1, XOR=2, NOT=3;
/**The java.awt.Shape encapsulated by this object.*/
private Shape shape;
/**The instance value of the maximum tolerance (MAXERROR) allowed in calculating the
* length of the curve segments of this ROI's shape.
*/
private double maxerror = ShapeRoi.MAXERROR;
/**The instance value of the coefficient (FLATNESS) used to
* obtain a flattened version of this ROI's shape.
*/
private double flatness = ShapeRoi.FLATNESS;
/**The instance value of MAXPOLY.*/
private int maxPoly = ShapeRoi.MAXPOLY;
/**If true then methods that manipulate this ROI's shape will work on
* a flattened version of the shape. */
private boolean flatten;
/**Flag which specifies how Roi objects will be constructed from closed (sub)paths having more than
* MAXPOLY and composed exclusively of line segments.
* If true then (sub)path will be parsed into a
* {@link ij.gui.Roi#TRACED_ROI}; else, into a {@link ij.gui.Roi#FREEROI}. */
private boolean forceTrace = false;
/**Flag which specifies if Roi objects constructed from open (sub)paths composed of only two line segments
* will be of type {@link ij.gui.Roi#ANGLE}.
* If true then (sub)path will be parsed into a {@link ij.gui.Roi#ANGLE};
* else, into a {@link ij.gui.Roi#POLYLINE}. */
private boolean forceAngle = false;
private Vector savedRois; //not really used any more
private static Stroke defaultStroke = new BasicStroke();
/** Constructs a ShapeRoi from an Roi. */
public ShapeRoi(Roi r) {
this(r, ShapeRoi.FLATNESS, ShapeRoi.MAXERROR, false, false, false, ShapeRoi.MAXPOLY);
}
/** Constructs a ShapeRoi from a Shape. */
public ShapeRoi(Shape s) {
super(s.getBounds());
AffineTransform at = new AffineTransform();
at.translate(-x, -y);
shape = new GeneralPath(at.createTransformedShape(s));
type = COMPOSITE;
}
/** Constructs a ShapeRoi from a Shape. */
public ShapeRoi(int x, int y, Shape s) {
super(x, y, s.getBounds().width, s.getBounds().height);
shape = new GeneralPath(s);
type = COMPOSITE;
}
/**Creates a ShapeRoi object from a "classical" ImageJ ROI.
* @param r An ij.gui.Roi object
* @param flatness The flatness factor used in convertion of curve segments into line segments.
* @param maxerror Error correction for calculating length of Bezeir curves.
* @param forceAngle flag used in the conversion of Shape objects to Roi objects (see {@link #shapeToRois()}.
* @param forceTrace flag for conversion of Shape objects to Roi objects (see {@link #shapeToRois()}.
* @param flatten if true then the shape of this ROI will be flattened
* (i.e., curve segments will be aproximated by line segments).
* @param maxPoly Roi objects constructed from shapes composed of linear segments fewer than this
* value will be of type {@link ij.gui.Roi#POLYLINE} or {@link ij.gui.Roi#POLYGON}; conversion of
* shapes with linear segments more than this value will result in Roi objects of type
* {@link ij.gui.Roi#FREELINE} or {@link ij.gui.Roi#FREEROI} unless the average side length
* is large (see {@link #shapeToRois()}).
*/
ShapeRoi(Roi r, double flatness, double maxerror, boolean forceAngle, boolean forceTrace, boolean flatten, int maxPoly) {
super(r.startX, r.startY, r.width, r.height);
this.type = COMPOSITE;
this.flatness = flatness;
this.maxerror = maxerror;
this.forceAngle = forceAngle;
this.forceTrace = forceTrace;
this.maxPoly= maxPoly;
this.flatten = flatten;
shape = roiToShape((Roi)r.clone());
}
/** Constructs a ShapeRoi from an array of variable length path segments. Each
segment consists of the segment type followed by 0-6 coordintes (0-3 end points and control
points). Depending on the type, a segment uses from 1 to 7 elements of the array. */
public ShapeRoi(float[] shapeArray) {
super(0,0,null);
shape = makeShapeFromArray(shapeArray);
Rectangle r = shape.getBounds();
x = r.x;
y = r.y;
width = r.width;
height = r.height;
state = NORMAL;
oldX=x; oldY=y; oldWidth=width; oldHeight=height;
AffineTransform at = new AffineTransform();
at.translate(-x, -y);
shape = new GeneralPath(at.createTransformedShape(shape));
flatness = ShapeRoi.FLATNESS;
maxerror = ShapeRoi.MAXERROR;
maxPoly = ShapeRoi.MAXPOLY;
flatten = false;
type = COMPOSITE;
}
/**Returns a deep copy of this. */
public synchronized Object clone() { // the equivalent of "operator=" ?
ShapeRoi sr = (ShapeRoi)super.clone();
sr.type = COMPOSITE;
sr.flatness = flatness;
sr.maxerror = maxerror;
sr.forceAngle = forceAngle;
sr.forceTrace = forceTrace;
//sr.setImage(imp); //wsr
sr.setShape(ShapeRoi.cloneShape(shape));
return sr;
}
/** Returns a deep copy of the argument. */
static Shape cloneShape(Shape rhs) {
if (rhs==null) return null;
else if (rhs instanceof Rectangle2D.Double)
return (Rectangle2D.Double)((Rectangle2D.Double)rhs).clone();
else if (rhs instanceof Ellipse2D.Double)
return (Ellipse2D.Double)((Ellipse2D.Double)rhs).clone();
else if (rhs instanceof Line2D.Double)
return (Line2D.Double)((Line2D.Double)rhs).clone();
else if (rhs instanceof Polygon)
return new Polygon(((Polygon)rhs).xpoints, ((Polygon)rhs).ypoints, ((Polygon)rhs).npoints);
else if (rhs instanceof GeneralPath)
return (GeneralPath)((GeneralPath)rhs).clone();
else
return makeShapeFromArray(getShapeAsArray(rhs, 0, 0));
}
/**********************************************************************************/
/*** Logical operations on shaped rois ****/
/**********************************************************************************/
/**Unary union operator.
* The caller is set to its union with the argument.
* @return the union of this and sr
*/
public ShapeRoi or(ShapeRoi sr) {return unaryOp(sr, OR);}
/**Unary intersection operator.
* The caller is set to its intersection with the argument (i.e., the overlapping regions between the
* operands).
* @return the overlapping regions between this and sr
*/
public ShapeRoi and(ShapeRoi sr) {return unaryOp(sr, AND);}
/**Unary exclusive or operator.
* The caller is set to the non-overlapping regions between the operands.
* @return the union of the non-overlapping regions of this and sr
* @see ij.gui.Roi#xor(Roi[])
* @see ij.gui.Overlay#xor(int[])
*/
public ShapeRoi xor(ShapeRoi sr) {return unaryOp(sr, XOR);}
/**Unary subtraction operator.
* The caller is set to the result of the operation between the operands.
* @return this subtracted from sr
*/
public ShapeRoi not(ShapeRoi sr) {return unaryOp(sr, NOT);}
ShapeRoi unaryOp(ShapeRoi sr, int op) {
AffineTransform at = new AffineTransform();
at.translate(x, y);
Area a1 = new Area(at.createTransformedShape(getShape()));
at = new AffineTransform();
at.translate(sr.x, sr.y);
Area a2 = new Area(at.createTransformedShape(sr.getShape()));
try {
switch (op) {
case OR: a1.add(a2); break;
case AND: a1.intersect(a2); break;
case XOR: a1.exclusiveOr(a2); break;
case NOT: a1.subtract(a2); break;
}
} catch(Exception e) {}
Rectangle r = a1.getBounds();
at = new AffineTransform();
at.translate(-r.x, -r.y);
setShape(new GeneralPath(at.createTransformedShape(a1)));
x = r.x;
y = r.y;
cachedMask = null;
return this;
}
/**********************************************************************************/
/*** Interconversions between "regular" rois and shaped rois ****/
/**********************************************************************************/
/**Converts the Roi argument to an instance of java.awt.Shape.
* Currently, the following conversions are supported:| Roi class | Roi type | Shape | <
|---|---|---|
| ij.gui.Roi | Roi.RECTANGLE | java.awt.geom.Rectangle2D.Double |
| ij.gui.OvalRoi | Roi.OVAL | java.awt.Polygon of the corresponding traced roi |
| ij.gui.Line | Roi.LINE | java.awt.geom.Line2D.Double |
| ij.gui.PolygonRoi | Roi.POLYGON | java.awt.Polygon or (if subpixel resolution) closed java.awt.geom.GeneralPath |
| ij.gui.PolygonRoi | Roi.FREEROI | java.awt.Polygon or (if subpixel resolution) closed java.awt.geom.GeneralPath |
| ij.gui.PolygonRoi | Roi.TRACED_ROI | java.awt.Polygon or (if subpixel resolution) closed java.awt.geom.GeneralPath |
| ij.gui.PolygonRoi | Roi.POLYLINE | open java.awt.geom.GeneralPath |
| ij.gui.PolygonRoi | Roi.FREELINE | open java.awt.geom.GeneralPath |
| ij.gui.PolygonRoi | Roi.ANGLE | open java.awt.geom.GeneralPath |
| ij.gui.ShapeRoi | Roi.COMPOSITE | shape of argument |
| ij.gui.ShapeRoi | ShapeRoi.NO_TYPE | null |
| Shape type | Roi class | Roi type |
|---|---|---|
| java.awt.geom.Rectangle2D.Double | ij.gui.Roi | Roi.RECTANGLE |
| java.awt.geom.Ellipse2D.Double | ij.gui.OvalRoi | Roi.OVAL |
| java.awt.geom.Line2D.Double | ij.gui.Line | Roi.LINE |
| java.awt.Polygon | ij.gui.PolygonRoi | Roi.POLYGON |
java.awt.geom.GeneralPath is converted following these rules:
| Segment types | Number of segments |
Closed path | Value of forceAngle |
Value of forceTrace | Roi type |
|---|---|---|---|---|---|
| lines only: | 0 | ShapeRoi.NO_TYPE | |||
| 1 | ShapeRoi.NO_TYPE | ||||
| 2 | Y | ShapeRoi.NO_TYPE | |||
| N | Roi.LINE | ||||
| 3 | Y | N | Roi.POLYGON | ||
| N | Y | Roi.ANGLE | |||
| N | N | Roi.POLYLINE | |||
| 4 | Y | Roi.RECTANGLE | |||
| N | Roi.POLYLINE | ||||
| <= MAXPOLY | Y | Roi.POLYGON | |||
| N | Roi.POLYLINE | ||||
| > MAXPOLY | Y | Y | Roi.TRACED_ROI | ||
| N | Roi.FREEROI | ||||
| N | Roi.FREELINE | ||||
| anything else: | <= 2 | ShapeRoi.NO_TYPE | |||
| > 2 | ShapeRoi.SHAPE_ROI |
java.awt.geom.GeneralPath to ij.gui.Roi.
* @param nSegments The number of segments that compose the path (= number of vertices for a polygon)
* @param polygonLength length of polygon in pixels, or NaN if curved segments
* @param horizontalVerticalIntOnly Indicates whether the GeneralPath is composed of only vertical and horizontal lines with integer coordinates
* @param forceTrace Indicates that closed shapes with horizontalVerticalIntOnly=true should become TRACED_ROIs
* @param closed Indicates a closed GeneralPath
* @see #shapeToRois()
* @return a type flag like Roi.RECTANGLE or NO_TYPE if the type cannot be determined
*/
private int guessType(int nSegments, double polygonLength, boolean horizontalVerticalIntOnly, boolean forceTrace, boolean closed) {
int roiType = Roi.RECTANGLE;
if (Double.isNaN(polygonLength)) {
roiType = Roi.COMPOSITE;
} else {
// For more segments, they should be longer to qualify for a polygon with handles:
// The threshold for the average segment length is 4.0 for 4 segments, 16.0 for 64 segments, 32.0 for 256 segments
boolean longEdges = polygonLength/(nSegments*Math.sqrt(nSegments)) >= 2;
if (nSegments < 2)
roiType = NO_TYPE;
else if (nSegments == 2)
roiType = closed ? NO_TYPE : Roi.LINE;
else if (nSegments == 3 && !closed && forceAngle)
roiType = Roi.ANGLE;
else if (nSegments == 4 && closed && horizontalVerticalIntOnly && longEdges && !forceTrace && !this.forceTrace)
roiType = Roi.RECTANGLE;
else if (closed && horizontalVerticalIntOnly && (!longEdges || forceTrace || this.forceTrace))
roiType = Roi.TRACED_ROI;
else if (nSegments <= MAXPOLY || longEdges)
roiType = closed ? Roi.POLYGON : Roi.POLYLINE;
else
roiType = closed ? Roi.FREEROI : Roi.FREELINE;
}
//IJ.log("guessType n= "+nSegments+" len="+polygonLength+" longE="+(polygonLength/(nSegments*Math.sqrt(nSegments)) >= 2)+" hvert="+horizontalVerticalIntOnly+" clos="+closed+" -> "+roiType);
return roiType;
}
/**Creates a 'classical' (non-Shape) Roi object based on the arguments.
* @see #shapeToRois()
* @param xPoints the x coordinates
* @param yPoints the y coordinates
* @param type the type flag
* @return a ij.gui.Roi object or null
*/
private Roi createRoi(float[] xPoints, float[] yPoints, int roiType) {
if (roiType == NO_TYPE || roiType == Roi.COMPOSITE) return null;
Roi roi = null;
if (xPoints == null || yPoints == null || xPoints.length != yPoints.length || xPoints.length==0) return null;
Tools.addToArray(xPoints, (float)getXBase());
Tools.addToArray(yPoints, (float)getYBase());
switch(roiType) {
case Roi.LINE: roi = new ij.gui.Line(xPoints[0],yPoints[0],xPoints[1],yPoints[1]); break;
case Roi.RECTANGLE:
double[] xMinMax = Tools.getMinMax(xPoints);
double[] yMinMax = Tools.getMinMax(yPoints);
roi = new Roi((int)xMinMax[0], (int)yMinMax[0],
(int)xMinMax[1] - (int)xMinMax[0], (int)yMinMax[1] - (int)yMinMax[0]);
break;
case TRACED_ROI:
roi = new PolygonRoi(toIntR(xPoints), toIntR(yPoints), xPoints.length, roiType);
break;
default:
roi = new PolygonRoi(xPoints, yPoints, xPoints.length, roiType);
break;
}
return roi;
}
/**********************************************************************************/
/*** Geometry ****/
/**********************************************************************************/
/** Checks whether the center of the specified pixel inside of this ROI's shape boundaries.
* Note the ImageJ convention of 0.5 pixel shift between outline and pixel center,
* i.e., pixel (0,0) is enclosed by the rectangle spanned between (0,0) and (1,1).
* The value slightly below 0.5 is for rounding according to the ImageJ convention
* (which is opposite to that of the java.awt.Shape class):
* In ImageJ, points exactly at the left (right) border are considered outside (inside);
* points exactly on horizontal borders, are considered outside (inside) at the border
* with the lower (higher) y.
*/
public boolean contains(int x, int y) {
if (shape==null) return false;
return shape.contains(x-this.x+0.494, y-this.y+0.49994);
}
/** Returns whether coordinate (x,y) is contained in the Roi.
* Note that the coordinate (0,0) is the top-left corner of pixel (0,0).
* Use contains(int, int) to determine whether a given pixel is contained in the Roi. */
public boolean containsPoint(double x, double y) {
if (!super.containsPoint(x, y))
return false;
return shape.contains(x-this.x+1e-3, y-this.y+1e-6); //adding a bit to reduce the likelyhood of numerical errors at integers
}
/** Returns the perimeter of this ShapeRoi. */
public double getLength() {
if (width==0 && height==0)
return 0.0;
return parsePath(shape.getPathIterator(new AffineTransform()), GET_LENGTH, null);
}
/** Returns a path iterator for this ROI's shape containing no curved (only straight) segments */
PathIterator getFlatteningPathIterator(Shape s, double fl) {
return s.getPathIterator(new AffineTransform(),fl);
}
/**Length of the control polygon of the cubic Bézier curve argument, in double precision.*/
double cplength(CubicCurve2D.Double c) {
return Math.sqrt(sqr(c.ctrlx1-c.x1) + sqr(c.ctrly1-c.y1)) +
Math.sqrt(sqr(c.ctrlx2-c.ctrlx1) + sqr(c.ctrly2-c.ctrly1)) +
Math.sqrt(sqr(c.x2-c.ctrlx2) + sqr(c.y2-c.ctrly2));
}
/**Length of the control polygon of the quadratic Bézier curve argument, in double precision.*/
double qplength(QuadCurve2D.Double c) {
return Math.sqrt(sqr(c.ctrlx-c.x1) + sqr(c.ctrly-c.y1)) +
Math.sqrt(sqr(c.x2-c.ctrlx) + sqr(c.y2-c.ctrly));
}
/**Length of the chord between the end points of the cubic Bézier curve argument, in double precision.*/
double cclength(CubicCurve2D.Double c) {
return Math.sqrt(sqr(c.x2-c.x1) + sqr(c.y2-c.y1));
}
/**Length of the chord between the end points of the quadratic Bézier curve argument, in double precision.*/
double qclength(QuadCurve2D.Double c) {
return Math.sqrt(sqr(c.x2-c.x1) + sqr(c.y2-c.y1));
}
/**Calculates the length of a cubic Bézier curve specified in double precision.
* The algorithm is based on the theory presented in paper java.awt.geom.CubicCurve2D.Double.
* Please visit {@link Graphics Gems IV} for
* examples of other possible implementations in C and C++.
*/
double cBezLength(CubicCurve2D.Double c) {
double l = 0.0;
double cl = cclength(c);
double pl = cplength(c);
if((pl-cl)/2.0 > maxerror) {
CubicCurve2D.Double[] cc = cBezSplit(c);
for(int i=0; i<2; i++) l+=cBezLength(cc[i]);
return l;
}
l = 0.5*pl+0.5*cl;
return l;
}
/**Calculates the length of a quadratic Bézier curve specified in double precision.
* The algorithm is based on the theory presented in paper java.awt.geom.CubicCurve2D.Double.
* Please visit {@link Graphics Gems IV} for
* examples of other possible implementations in C and C++.
*/
double qBezLength(QuadCurve2D.Double c) {
double l = 0.0;
double cl = qclength(c);
double pl = qplength(c);
if((pl-cl)/2.0 > maxerror)
{
QuadCurve2D.Double[] cc = qBezSplit(c);
for(int i=0; i<2; i++) l+=qBezLength(cc[i]);
return l;
}
l = (2.0*pl+cl)/3.0;
return l;
}
/**Splits a cubic Bézier curve in half.
* @param c A cubic Bézier curve to be divided
* @return an array with the left and right cubic Bézier subcurves
*
*/
CubicCurve2D.Double[] cBezSplit(CubicCurve2D.Double c) {
CubicCurve2D.Double[] cc = new CubicCurve2D.Double[2];
for (int i=0; i<2 ; i++) cc[i] = new CubicCurve2D.Double();
c.subdivide(cc[0],cc[1]);
return cc;
}
/**Splits a quadratic Bézier curve in half.
* @param c A quadratic Bézier curve to be divided
* @return an array with the left and right quadratic Bézier subcurves
*
*/
QuadCurve2D.Double[] qBezSplit(QuadCurve2D.Double c) {
QuadCurve2D.Double[] cc = new QuadCurve2D.Double[2];
for(int i=0; i<2; i++) cc[i] = new QuadCurve2D.Double();
c.subdivide(cc[0],cc[1]);
return cc;
}
// c is an array of even length with x0, y0, x1, y1, ... ,xn, yn coordinate pairs
/**Scales a coordinate array with the size calibration of a 2D image.
* The array is modified in place.
* @param c Array of coordinates in double precision with a fixed structure:x0,y0,x1,y1,....,xn,yn and with even length of 2*(n+1).
* @param pw The x-scale of the image.
* @param ph The y-scale of the image.
* @param n number of values in c that should be modified (must be less or equal to the size of c
*
*/
void scaleCoords(double[] c, int n, double pw, double ph) {
for(int i=0; itask and rois argument it will:
* rois in case
* there is only one subpath, otherwise add this Roi unchanged to rois
* (task = ONE_ROI and rois non-null)
* task = GET_LENGTH
* (see @link #shapeToRois()} for details;
* @return Total length if task = GET_LENGTH.*/
double parsePath(PathIterator pIter, int task, ArrayList rois) {
if (pIter==null || pIter.isDone())
return 0.0;
double pw = 1.0, ph = 1.0;
if (imp!=null) {
Calibration cal = imp.getCalibration();
pw = cal.pixelWidth;
ph = cal.pixelHeight;
}
float xbase = (float)getXBase();
float ybase = (float)getYBase();
FloatArray xPoints = new FloatArray(); //vertex coordinates of current subpath
FloatArray yPoints = new FloatArray();
FloatArray shapeArray = new FloatArray(); //values for creating a GeneralPath for the current subpath
boolean getLength = task == GET_LENGTH;
int nSubPaths = 0; // the number of subpaths
boolean horVertOnly = true; // subpath has only horizontal or vertical lines
boolean closed = false;
//boolean success = false;
float[] fcoords = new float[6]; // unscaled float coordinates of the path segment
double[] coords = new double[6]; // scaled (calibrated) coordinates of the path segment
double startCalX = 0.0; // start x of subpath (scaled)
double startCalY = 0.0; // start y of subpath (scaled)
double lastCalX = 0.0; // x of previous point in the subpath (scaled)
double lastCalY = 0.0; // y of previous point in the subpath (scaled)
double pathLength = 0.0; // calibrated pathLength/perimeter of current curve
double totalLength = 0.0; // sum of all calibrated path lengths/perimeters
double uncalLength = 0.0; // uncalibrated length of polygon, NaN in case of curves
boolean done = false;
while (true) {
int segType = done ? NO_SEGMENT_ANY_MORE : pIter.currentSegment(fcoords); //read segment (if there is one more)
int nCoords = 0; //will be number of coordinates supplied with the segment
if (!done) {
nCoords = nCoords(segType);
if (getLength) { //make scaled coodinates to calculate the length
pIter.currentSegment(coords);
scaleCoords(coords, nCoords, pw, ph);
}
pIter.next();
done = pIter.isDone();
}
//IJ.log("segType="+segType+" nCoord="+nCoords+" done="+done+" nPoi="+nPoints+" len="+pathLength);
if (segType == NO_SEGMENT_ANY_MORE || (segType == PathIterator.SEG_MOVETO && xPoints.size()>0)) {
// subpath finished: analyze it & create roi if appropriate
closed = closed || (xPoints.size()>0 && xPoints.get(0) == xPoints.getLast() && yPoints.get(0) == yPoints.getLast());
float[] xpf = xPoints.toArray();
float[] ypf = yPoints.toArray();
if (Double.isNaN(uncalLength) || !allInteger(xpf) || !allInteger(ypf))
horVertOnly = false; //allow conversion to rectangle or traced roi only for integer coordinates
boolean forceTrace = getLength && (!done || nSubPaths>0); //when calculating the length for >1 subpath, assume traced rois if it can be such
int roiType = guessType(xPoints.size(), uncalLength, horVertOnly, forceTrace, closed);
Roi roi = null;
if (roiType == COMPOSITE && rois != null) { //for ShapeRois with curves, we have the length from the path already, make roi only if needed
Shape shape = makeShapeFromArray(shapeArray.toArray()); //the curved subpath (image pixel coordinates)
FloatPolygon fp = getFloatPolygon(shape, FLATNESS, /*separateSubpaths=*/ false, /*addPointForClose=*/ false, /*absoluteCoord=*/ false);
roi = new PolygonRoi(fp, FREEROI);
} else if (roiType != NO_TYPE) { //NO_TYPE looks like an empty roi; only return non-empty rois
roi = createRoi(xpf, ypf, roiType);
}
if (rois != null && roi != null)
rois.add(roi);
if (task == ONE_ROI) {
if (rois.size() > 1) { //we can't make a single roi from this; so we can only keep the roi as it is
rois.clear();
rois.add(this);
return 0.0;
}
}
if (getLength && roi != null && !Double.isNaN(uncalLength)) {
roi.setImage(imp); //calibration
pathLength = roi.getLength();//we don't use the path length of the Shape; e.g. for traced rois ImageJ has a better algorithm
roi.setImage(null);
}
totalLength += pathLength;
}
if (segType == NO_SEGMENT_ANY_MORE) // b r e a k t h e l o o p
return getLength ? totalLength : 0;
closed = false;
switch(segType) {
case PathIterator.SEG_MOVETO: //we start a new subpath
xPoints.clear();
yPoints.clear();
shapeArray.clear();
nSubPaths++;
pathLength = 0;
startCalX = coords[0];
startCalY = coords[1];
closed = false;
horVertOnly = true;
break;
case PathIterator.SEG_LINETO:
pathLength += Math.sqrt(sqr(lastCalY-coords[1])+sqr(lastCalX-coords[0]));
break;
case PathIterator.SEG_QUADTO:
if (getLength) {
QuadCurve2D.Double curve = new QuadCurve2D.Double(lastCalX,lastCalY,coords[0],coords[2],coords[2],coords[3]);
pathLength += qBezLength(curve);
}
uncalLength = Double.NaN; // not a polygon
break;
case PathIterator.SEG_CUBICTO:
if (getLength) {
CubicCurve2D.Double curve = new CubicCurve2D.Double(lastCalX,lastCalY,coords[0],coords[1],coords[2],coords[3],coords[4],coords[5]);
pathLength += cBezLength(curve);
}
uncalLength = Double.NaN; // not a polygon
break;
case PathIterator.SEG_CLOSE:
pathLength += Math.sqrt(sqr(lastCalX-startCalX) + sqr(lastCalY-startCalY));
fcoords[0] = xPoints.get(0); //destination coordinates; with these we can handle it as SEG_LINETO
fcoords[1] = yPoints.get(0);
closed = true;
break;
default:
break;
}
if (xPoints.size()>0 && (segType == PathIterator.SEG_LINETO || segType == PathIterator.SEG_CLOSE)) {
float dx = fcoords[0] - xPoints.getLast();
float dy = fcoords[1] - yPoints.getLast();
uncalLength += Math.sqrt(sqr(dx) + sqr(dy));
if (dx != 0f && dy != 0f) horVertOnly = false;
}
if (nCoords > 0) {
xPoints.add(fcoords[nCoords - 2]); // the last coordinates are the end point of the segment
yPoints.add(fcoords[nCoords - 1]);
lastCalX = coords[nCoords - 2];
lastCalY = coords[nCoords - 1];
}
shapeArray.add(segType);
addOffset(fcoords, nCoords, xbase, ybase); // shift the shape to image origin
shapeArray.add(fcoords, nCoords(segType));
}
}
/** Non-destructively draws the shape of this object on the associated ImagePlus. */
public void draw(Graphics g) {
Color color = strokeColor!=null? strokeColor:ROIColor;
boolean isActiveOverlayRoi = !overlay && isActiveOverlayRoi();
//IJ.log("draw: "+overlay+" "+isActiveOverlayRoi);
if (isActiveOverlayRoi) {
if (color==Color.cyan)
color = Color.magenta;
else
color = Color.cyan;
}
if (fillColor!=null) color = fillColor;
g.setColor(color);
AffineTransform aTx = (((Graphics2D)g).getDeviceConfiguration()).getDefaultTransform();
Graphics2D g2d = (Graphics2D)g;
if (stroke!=null && !isActiveOverlayRoi)
g2d.setStroke((ic!=null&&ic.getCustomRoi())||isCursor()?stroke:getScaledStroke());
mag = getMagnification();
int basex=0, basey=0;
if (ic!=null) {
Rectangle r = ic.getSrcRect();
basex=r.x; basey=r.y;
}
aTx.setTransform(mag, 0.0, 0.0, mag, -basex*mag, -basey*mag);
aTx.translate(getXBase(), getYBase());
if (fillColor!=null) {
if (isActiveOverlayRoi) {
g2d.setColor(Color.cyan);
g2d.draw(aTx.createTransformedShape(shape));
} else {
g2d.fill(aTx.createTransformedShape(shape));
if (strokeColor!=null) {
g.setColor(strokeColor);
g2d.draw(aTx.createTransformedShape(shape));
}
}
} else
g2d.draw(aTx.createTransformedShape(shape));
if (stroke!=null) g2d.setStroke(defaultStroke);
if (Toolbar.getToolId()==Toolbar.OVAL)
drawRoiBrush(g);
if (state!=NORMAL && imp!=null && imp.getRoi()!=null)
showStatus();
if (updateFullWindow)
{updateFullWindow = false; imp.draw();}
}
public void drawRoiBrush(Graphics g) {
g.setColor(ROIColor);
int size = Toolbar.getBrushSize();
if (size==0 || ic==null)
return;
int flags = ic.getModifiers();
if ((flags&16)==0) return; // exit if mouse button up
int osize = size;
size = (int)(size*mag);
Point p = ic.getCursorLoc();
int sx = ic.screenX(p.x);
int sy = ic.screenY(p.y);
int offset = (int)Math.round(ic.getMagnification()/2.0);
if ((osize&1)==0)
offset=0; // not needed when brush width even
g.drawOval(sx-size/2+offset, sy-size/2+offset, size, size);
}
/**Draws the shape of this object onto the specified ImageProcessor.
* java.awt.Shape object encapsulated by this
* to the argument.
* setShape(ShapeRoi.cloneShape(shape)).
* @return false if the argument is null.
*/
boolean setShape(Shape rhs) {
boolean result = true;
if (rhs==null) return false;
if (shape.equals(rhs)) return false;
shape = rhs;
type = Roi.COMPOSITE;
Rectangle rect = shape.getBounds();
width = rect.width;
height = rect.height;
return true;
}
/**Returns the element with the smallest value in the array argument.*/
private int min(int[] array) {
int val = array[0];
for (int i=1; i