package ij.gui;
import ij.*;
import ij.process.*;
import ij.measure.*;
import ij.plugin.Straightener;
import ij.plugin.frame.Recorder;
import ij.plugin.CalibrationBar;
import java.awt.*;
import java.awt.image.*;
import java.util.Iterator;
import java.util.NoSuchElementException;
import java.awt.event.*;
import java.awt.geom.*;

/** This class represents a straight line selection. */
public class Line extends Roi {
	public int x1, y1, x2, y2;	// the line end points as integer coordinates, for compatibility only
	public double x1d, y1d, x2d, y2d;	// the line using sub-pixel coordinates
	protected double x1R, y1R, x2R, y2R;  // the line, relative to base of subpixel bounding rect 'bounds'
	protected double startxd, startyd;
	static boolean widthChanged;
	private boolean dragged;
	private int mouseUpCount;

	/** Creates a new straight line selection using the specified
		starting and ending offscreen integer coordinates. */
	public Line(int ox1, int oy1, int ox2, int oy2) {
		this((double)ox1, (double)oy1, (double)ox2, (double)oy2);
	}

	/** Creates a new straight line selection using the specified
		starting and ending offscreen double coordinates. */
	public Line(double ox1, double oy1, double ox2, double oy2) {
		super((int)(ox1+0.5), (int)(oy1+0.5), 0, 0);
		type = LINE;
		updateCoordinates(ox1, oy1, ox2, oy2);
		if (!(this instanceof Arrow) && lineWidth>1)
			updateWideLine(lineWidth);
		updateClipRect();
		oldX=x; oldY=y; oldWidth=width; oldHeight=height;
		state = NORMAL;
	}

	/** Creates a new straight line selection using the specified
		starting and ending offscreen coordinates. */
	public static Line create(double x1, double y1, double x2, double y2) {
		return new Line(x1, y1, x2, y2);
	}

	/** Starts the process of creating a new user-generated straight line
		selection. 'sx' and 'sy' are screen coordinates that specify
		the start of the line. The user will determine the end of the line
		interactively using rubber banding. */
	public Line(int sx, int sy, ImagePlus imp) {
		super(sx, sy, imp);
		type = LINE;
		startxd = offScreenXD(sx);
		startyd = offScreenYD(sy);
		if (!magnificationForSubPixel()) {
			startxd = Math.round(startxd);
			startyd = Math.round(startyd);
		}
		updateCoordinates(startxd, startyd, startxd, startyd);
		if (!(this instanceof Arrow) && lineWidth>1)
			updateWideLine(lineWidth);
	}

	/**
	* @deprecated
	* replaced by Line(int, int, int, int)
	*/
	public Line(int ox1, int oy1, int ox2, int oy2, ImagePlus imp) {
		this(ox1, oy1, ox2, oy2);
		setImage(imp);
	}

	protected void grow(int sx, int sy) { //mouseDragged
		drawLine(sx, sy);
		dragged = true;
	}

	public void mouseMoved(MouseEvent e) {
		drawLine(e.getX(), e.getY());
	}

	protected void handleMouseUp(int screenX, int screenY) {
		mouseUpCount++;
		if (Prefs.enhancedLineTool && mouseUpCount==1 && !dragged)
			return;
		state = NORMAL;
		if (imp==null) return;
		imp.draw(clipX-5, clipY-5, clipWidth+10, clipHeight+10);
		if (Recorder.record) {
			String method = (this instanceof Arrow)?"makeArrow":"makeLine";
			Recorder.record(method, x1, y1, x2, y2);
		}
		if (getLength()==0.0)
			imp.deleteRoi();
	}

	protected void drawLine(int sx, int sy) {
		double xend = offScreenXD(sx);
		double yend = offScreenYD(sy);
		if (xend<0.0) xend=0.0; if (yend<0.0) yend=0.0;
		if (xend>xMax) xend=xMax; if (yend>yMax) yend=yMax;
		double xstart=getXBase()+x1R, ystart=getYBase()+y1R;
		if (constrain) {
		    int i=0;
	        double dy = Math.abs(yend-ystart);
	        double dx = Math.abs(xend-xstart);
	        double comp = dy / dx;
	        for (;i<PI_SEARCH.length; i++) {
	            if(comp < PI_SEARCH[i]) {
	                break;
	            }
	        }
	        if (i < PI_SEARCH.length) {
	            if(yend > ystart) {
	                yend = ystart + dx*PI_MULT[i];
	            } else {
	                yend = ystart - dx*PI_MULT[i];
	            }
	        } else {
	            xend = xstart;
	        }
		}
		if (!magnificationForSubPixel() || IJ.controlKeyDown()) {  //during creation, CTRL enforces integer coordinates
			xstart=Math.round(xstart); ystart=Math.round(ystart);
			xend=Math.round(xend);     yend=Math.round(yend);
		}
		updateCoordinates(xstart, ystart, xend, yend);
		updateClipRect();
		imp.draw(clipX, clipY, clipWidth, clipHeight);
		oldX=x; oldY=y;
		oldWidth=width; oldHeight=height;
	}

	/** Used for angle searches in line ROI creation: tan = y/x for angle limits 1/2*45 degrees, and 3/2*45 deg */
	private static final double[] PI_SEARCH = {Math.tan(Math.PI/8), Math.tan((3*Math.PI)/8)};
	private static final double[] PI_MULT = {0, 1}; // y/x for horizontal (0 degrees) and 45 deg

	void move(int sx, int sy) {
		int xNew = offScreenX(sx);
		int yNew = offScreenY(sy);
		x += xNew - startxd;
		y += yNew - startyd;
		clipboard=null;
		startxd = xNew;
		startyd = yNew;
		updateClipRect();
		if (ignoreClipRect)
			imp.draw();
		else
			imp.draw(clipX, clipY, clipWidth, clipHeight);
		oldX = x;
		oldY = y;
		oldWidth = width;
		oldHeight=height;
	}

	protected void moveHandle(int sx, int sy) {
		if (constrain && activeHandle == 2) {  // constrain translation in 90deg steps
			int dx = sx - previousSX;
			int dy = sy - previousSY;
			if (Math.abs(dx) > Math.abs(dy))
				dy = 0;
			else
				dx = 0;
			sx = previousSX + dx;
			sy = previousSY + dy;
		}
		double ox = offScreenXD(sx);
		double oy = offScreenYD(sy);
		double x1d=getXBase()+x1R, y1d=getYBase()+y1R;
		double x2d=getXBase()+x2R, y2d=getYBase()+y2R;
		double length = Math.sqrt(sqr(x2d-x1d) + sqr(y2d-y1d));
		switch (activeHandle) {
			case 0:
                double dx = ox-x1d;
                double dy = oy-y1d;
                x1d=ox;
                y1d=oy;
                if(center){
                    x2d -= dx;
                    y2d -= dy;
                }
				if (aspect){
					double ratio = length/(Math.sqrt(sqr(x2d-x1d) + sqr(y2d-y1d)));
					double xcd = x1d+(x2d-x1d)/2;
					double ycd = y1d+(y2d-y1d)/2;

					if(center){
						x1d=xcd-ratio*(xcd-x1d);
						x2d=xcd+ratio*(x2d-xcd);
						y1d=ycd-ratio*(ycd-y1d);
						y2d=ycd+ratio*(y2d-ycd);
					} else {
						x1d=x2d-ratio*(x2d-x1d);
						y1d=y2d-ratio*(y2d-y1d);
					}

				}
                break;
			case 1:
                dx = ox-x2d;
                dy = oy-y2d;
                x2d=ox;
                y2d=oy;
                if(center){
                    x1d -= dx;
                    y1d -= dy;
                }
				if(aspect){
					double ratio = length/(Math.sqrt((x2d-x1d)*(x2d-x1d) + (y2d-y1d)*(y2d-y1d)));
					double xcd = x1d+(x2d-x1d)/2;
					double ycd = y1d+(y2d-y1d)/2;

					if(center){
						x1d=xcd-ratio*(xcd-x1d);
						x2d=xcd+ratio*(x2d-xcd);
						y1d=ycd-ratio*(ycd-y1d);
						y2d=ycd+ratio*(y2d-ycd);
					} else {
						x2d=x1d+ratio*(x2d-x1d);
						y2d=y1d+ratio*(y2d-y1d);
					}

				}
                break;
			case 2:
				dx = ox-(x1d+(x2d-x1d)/2);
				dy = oy-(y1d+(y2d-y1d)/2);
				x1d+=dx; y1d+=dy; x2d+=dx; y2d+=dy;
				break;
		}
		if (constrain) {
			double dx = Math.abs(x1d-x2d);
			double dy = Math.abs(y1d-y2d);
			double xcd = Math.min(x1d,x2d)+dx/2;
			double ycd = Math.min(y1d,y2d)+dy/2;

			//double ratio = length/(Math.sqrt((x2d-x1d)*(x2d-x1d) + (y2d-y1d)*(y2d-y1d)));
			if (activeHandle==0) {
				if (dx>=dy) {
					if(aspect){
						if(x2d>x1d) x1d=x2d-length;
						else x1d=x2d+length;
					}
					y1d = y2d;
					if(center) {
						y1d=y2d=ycd;
						if(aspect){
							if(xcd>x1d) {
								x1d=xcd-length/2;
								x2d=xcd+length/2;
							}
							else{
								x1d=xcd+length/2;
								x2d=xcd-length/2;
							}
						}
					}
				} else {
					if(aspect){
						if(y2d>y1d) y1d=y2d-length;
						else y1d=y2d+length;
					}
					x1d = x2d;
					if(center){
						x1d=x2d=xcd;
						if(aspect){
							if(ycd>y1d) {
								y1d=ycd-length/2;
								y2d=ycd+length/2;
							}
							else{
								y1d=ycd+length/2;
								y2d=ycd-length/2;
							}
						}
					}
				}
			} else if (activeHandle==1) {
				if (dx>=dy) {
					if(aspect){
						if(x1d>x2d) x2d=x1d-length;
						else x2d=x1d+length;
					}
					y2d= y1d;
					if(center){
						y1d=y2d=ycd;
						if(aspect){
							if(xcd>x1d) {
								x1d=xcd-length/2;
								x2d=xcd+length/2;
							}
							else{
								x1d=xcd+length/2;
								x2d=xcd-length/2;
							}
						}
					}
				} else {
					if(aspect){
						if(y1d>y2d) y2d=y1d-length;
						else y2d=y1d+length;
					}
					x2d = x1d;
					if(center){
						x1d=x2d=xcd;
						if(aspect){
							if(ycd>y1d) {
								y1d=ycd-length/2;
								y2d=ycd+length/2;
							}
							else{
								y1d=ycd+length/2;
								y2d=ycd-length/2;
							}
						}
					}
				}
			}
		}
		if (!magnificationForSubPixel()) {
			x1d = Math.round(x1d); y1d = Math.round(y1d);
			x2d = Math.round(x2d); y2d = Math.round(y2d);
		}
		updateCoordinates(x1d, y1d, x2d, y2d);
		updateClipRect();
		imp.draw(clipX, clipY, clipWidth, clipHeight);
		oldX = x;
		oldY = y;
		oldWidth = width;
		oldHeight = height;
	}

	protected void mouseDownInHandle(int handle, int sx, int sy) {
		super.mouseDownInHandle(handle, sx, sy); //sets state, activeHandle, previousSX&Y
		if (getStrokeWidth()<=3)
			ic.setCursor(new Cursor(Cursor.CROSSHAIR_CURSOR));
	}

	/** Sets the x1d, y1d, x2d, y2d line end points,
	 *  the (legacy) integer coordinates of the end points x1, y1, x2, y2
	 *  the 'bounds' subpixel rectangle of the Roi superclass (spanned by the end points),
	 *  the int x, y, width, height integer bounds of the superclass (these enclose
	 *  the 'draw' area for 1 pixel width), and
	 *  the coordinates x1R, y1R, x2R, y2R relative to the base x, y of the 'bounds' */
	void updateCoordinates(double x1d, double y1d, double x2d, double y2d) {
		this.x1d = x1d; this.y1d = y1d;
		this.x2d = x2d; this.y2d = y2d;
		Rectangle2D.Double bounds = this.bounds;  //local variable (this.bounds may become null asynchronously upon nudge)
		if (bounds == null) bounds = new Rectangle2D.Double();
		bounds.x = Math.min(x1d, x2d);
		bounds.y = Math.min(y1d, y2d);
		bounds.width  = Math.abs(x2d - x1d);
		bounds.height = Math.abs(y2d - y1d);
		setIntBounds(bounds); //sets x, y, width, height
		x1R = x1d - bounds.x; y1R = y1d - bounds.y;
		x2R = x2d - bounds.x; y2R = y2d - bounds.y;
		x1=(int)x1d; y1=(int)y1d; x2=(int)x2d; y2=(int)y2d;
		this.bounds = bounds;
	}

	/** Draws this line on the image. */
	public void draw(Graphics g) {
		Color color =  strokeColor!=null? strokeColor:ROIColor;
		boolean isActiveOverlayRoi = !overlay && isActiveOverlayRoi();
		mag = getMagnification();
		if (isActiveOverlayRoi) {
			if (color==Color.cyan)
				color = Color.magenta;
			else
				color = Color.cyan;
		}
		g.setColor(color);
		x1d=getXBase()+x1R; y1d=getYBase()+y1R; x2d=getXBase()+x2R; y2d=getYBase()+y2R;
		x1=(int)x1d; y1=(int)y1d; x2=(int)x2d; y2=(int)y2d;
		int sx1 = screenXD(x1d);
		int sy1 = screenYD(y1d);
		int sx2 = screenXD(x2d);
		int sy2 = screenYD(y2d);
		int sx3 = sx1 + (sx2-sx1)/2;
		int sy3 = sy1 + (sy2-sy1)/2;
		Graphics2D g2d = (Graphics2D)g;
		setRenderingHint(g2d);
		boolean cbar = overlay && mag<1.0 && Math.abs(getStrokeWidth()-CalibrationBar.STROKE_WIDTH)<0.0001;
		if (stroke!=null && !isActiveOverlayRoi && !cbar)
			g2d.setStroke(getScaledStroke());
		else if (cbar)
			g2d.setStroke(onePixelWide);
		if (wideLine && !isActiveOverlayRoi && !cbar) {
			double dx = sx2 - sx1;
			double dy = sy2 - sy1;
			double len = length(dx, dy);
			dx *= 0.5*mag/len;	//half-pixel extension, corresponding to getFloatPolygon or convertLineToArea
			dy *= 0.5*mag/len;
			g2d.draw(new Line2D.Double(sx1-dx, sy1-dy, sx2+dx, sy2+dy));
		} else
			g.drawLine(sx1, sy1, sx2, sy2);
		if (wideLine && !overlay) {
			g2d.setStroke(onePixelWide);
			g.setColor(getColor());
			g.drawLine(sx1, sy1, sx2, sy2);
		}
		if (!overlay) {
			handleColor = strokeColor!=null?strokeColor:ROIColor;
			drawHandle(g, sx1, sy1);
			handleColor=Color.white;
			drawHandle(g, sx2, sy2);
			drawHandle(g, sx3, sy3);
		}
		if (state!=NORMAL)
			showStatus();
		if (updateFullWindow)
			{updateFullWindow = false; imp.draw();}
	}

	public void showStatus() {
		IJ.showStatus(imp.getLocationAsString((int)Math.round(x2d),(int)Math.round(y2d))+
				", angle=" + IJ.d2s(getAngle()) + ", length=" + IJ.d2s(getLength()));
	}

	public double getAngle() {
		return getFloatAngle(x1d, y1d, x2d, y2d);
	}

	/** Returns the length of this line. */
	public double getLength() {
		if (imp==null || IJ.altKeyDown())
			return getRawLength();
		else {
			Calibration cal = imp.getCalibration();
			return Math.sqrt(sqr((x2d-x1d)*cal.pixelWidth) + sqr((y2d-y1d)*cal.pixelHeight));
		}
	}

	/** Returns the length of this line in pixels. */
	public double getRawLength() {
		return Math.sqrt(sqr(x2d-x1d)+sqr(y2d-y1d));
	}

	/** Returns the pixel values along this line.
	 *  The line roi must have an associated ImagePlus */
	public double[] getPixels() {
			double[] profile;
			if (getStrokeWidth()<=1) {
				ImageProcessor ip = imp.getProcessor();
				profile = ip.getLine(x1d, y1d, x2d, y2d);
			} else {
				Straightener s = new Straightener();
				ImageProcessor ip2 = s.straightenLine(imp,this,0);
				if (ip2==null)
					return new double[0];
				int width = ip2.getWidth();
				int height = ip2.getHeight();
				if (ip2 instanceof FloatProcessor)
					return ProfilePlot.getColumnAverageProfile(new Rectangle(0,0,width,height),ip2);
				profile = new double[width];
				double[] aLine;
				ip2.setInterpolate(false);
				for (int y=0; y<height; y++) {
					aLine = ip2.getLine(0, y, width-1, y);
					for (int i=0; i<width; i++)
						profile[i] += aLine[i];
				}
				for (int i=0; i<width; i++)
					profile[i] /= height;
			}
			return profile;
	}

	/** Returns, as a Polygon, the two points that define this line. */
	public Polygon getPoints() {
		Polygon p = new Polygon();
		p.addPoint((int)Math.round(x1d), (int)Math.round(y1d));
		p.addPoint((int)Math.round(x2d), (int)Math.round(y2d));
		return p;
	}

	/** Returns, as a FloatPolygon, the two points that define this line. */
	public FloatPolygon getFloatPoints() {
		FloatPolygon p = new FloatPolygon();
		p.addPoint((float)x1d, (float)y1d);
		p.addPoint((float)x2d, (float)y2d);
		return p;
	}

	/** If the width of this line is less than or equal to one, returns the
	 * starting and ending coordinates as a 2-point Polygon, or, if
	 * the width is greater than one, returns an outline of the line as
	 * a 4-point Polygon.
	 * @see #getFloatPolygon
	 * @see #getPoints
	 */
	public Polygon getPolygon() {
		FloatPolygon p = getFloatPolygon();
		return new Polygon(toIntR(p.xpoints), toIntR(p.ypoints), p.npoints);
	}

	/** If the width of this line is less than or equal to one, returns the
	 * starting and ending coordinates as a 2-point FloatPolygon, or, if
	 * the width is greater than one, returns an outline of the line as
	 * a 4-point FloatPolygon.
	 * @see #getFloatPoints
	 */
	public FloatPolygon getFloatPolygon() {
		return getFloatPolygon(getStrokeWidth());
	}

	/** Obsolete */
	public FloatPolygon getFloatPolygon(double strokeWidth) {
		FloatPolygon p = new FloatPolygon();
		if (strokeWidth <= 1) {
			p.addPoint((float)x1d, (float)y1d);
			p.addPoint((float)x2d, (float)y2d);
		} else {
			double dx = x2d - x1d;
			double dy = y2d - y1d;
			double len = length(dx, dy);
			dx *= 0.5/len;		// half unit vector in the direction of the line
			dy *= 0.5/len;		// when rotated 90 deg cw, this yields the vector (-dx, dy)
			double p1x = x1d + 0.5 - dx + dy*strokeWidth;  //0.5 pxl shift: area vs. line coordinate convention
			double p1y = y1d + 0.5 - dy - dx*strokeWidth;
			double p2x = x1d + 0.5 - dx - dy*strokeWidth;
			double p2y = y1d + 0.5 - dy + dx*strokeWidth;
			double p3x = x2d + 0.5 + dx - dy*strokeWidth;
			double p3y = y2d + 0.5 + dy + dx*strokeWidth;
			double p4x = x2d + 0.5 + dx + dy*strokeWidth;
			double p4y = y2d + 0.5 + dy - dx*strokeWidth;
			p.addPoint((float)p1x, (float)p1y);
			p.addPoint((float)p2x, (float)p2y);
			p.addPoint((float)p3x, (float)p3y);
			p.addPoint((float)p4x, (float)p4y);
		}
		return p;
	}

	/** Returns the number of points in this selection; equivalent to getPolygon().npoints. */
	public int size() {
		return getStrokeWidth()<=1?2:4;
	}

	/** If the width of this line is less than or equal to one, draws the line.
	 *  Otherwise draws the outline of the area of this line. */
	public void drawPixels(ImageProcessor ip) {
		boolean fillLine = getStrokeWidth()>1 && getWidth()<=1;
		if (fillLine)
			ip.setLineWidth((int)Math.round(getStrokeWidth()));
		else
			ip.setLineWidth(1);
		double x = getXBase();
		double y = getYBase();
		x1d=getXBase()+x1R; y1d=getYBase()+y1R; x2d=getXBase()+x2R; y2d=getYBase()+y2R;
		if (getStrokeWidth()<=1 || fillLine) {
			ip.moveTo((int)Math.round(x1d), (int)Math.round(y1d));
			ip.lineTo((int)Math.round(x2d), (int)Math.round(y2d));
		} else {
			Polygon p = getPolygon();
			ip.drawPolygon(p);
			updateFullWindow = true;
		}
	}

	public boolean contains(int x, int y) {
		if (getStrokeWidth()>1) {
			if ((x==x1&&y==y1) || (x==x2&&y==y2))
				return true;
			else
				return getPolygon().contains(x,y);
		} else
			return false;
	}

	protected void handleMouseDown(int sx, int sy) {
		super.handleMouseDown(sx, sy);
		startxd = ic.offScreenXD(sx);
		startyd = ic.offScreenYD(sy);
	}

	/** Returns a handle number if the specified screen coordinates are
		inside or near a handle, otherwise returns -1. */
	public int isHandle(int sx, int sy) {
		int size = HANDLE_SIZE+5;
		if (getStrokeWidth()>1) size += (int)Math.log(getStrokeWidth());
		int halfSize = size/2;
		int sx1 = screenXD(getXBase()+x1R) - halfSize;
		int sy1 = screenYD(getYBase()+y1R) - halfSize;
		int sx2 = screenXD(getXBase()+x2R) - halfSize;
		int sy2 = screenYD(getYBase()+y2R) - halfSize;
		int sx3 = sx1 + (sx2-sx1)/2-1;
		int sy3 = sy1 + (sy2-sy1)/2-1;
		if (sx>=sx1&&sx<=sx1+size&&sy>=sy1&&sy<=sy1+size) return 0;
		if (sx>=sx2&&sx<=sx2+size&&sy>=sy2&&sy<=sy2+size) return 1;
		if (sx>=sx3&&sx<=sx3+size+2&&sy>=sy3&&sy<=sy3+size+2) return 2;
		return -1;
	}

	/** Returns the default line width. Use getStrokeWidth()to
	 * get the width of a Line instance.
	 * @see #getStrokeWidth
	*/
	public static int getWidth() {
		return lineWidth;
	}

	/** Sets the default line width. Use setStrokeWidth()
	 * to set the width of a Line instance.
	 * @see #setStrokeWidth
	*/
	public static void setWidth(int w) {
		if (w<1) w = 1;
		int max = 500;
		if (w>max) {
			ImagePlus imp2 = WindowManager.getCurrentImage();
			if (imp2!=null) {
				max = Math.max(max, imp2.getWidth());
				max = Math.max(max, imp2.getHeight());
			}
			if (w>max) w = max;
		}
		lineWidth = w;
		widthChanged = true;
	}

	/* Sets the width of this line. */
	public void setStrokeWidth(float width) {
		super.setStrokeWidth(width);
		if (getStrokeColor()==Roi.getColor())
			wideLine = true;
	}

	protected int clipRectMargin() {
		return 4;
	}

	/** Nudge end point of line by one pixel. */
	public void nudgeCorner(int key) {
		if (ic==null) return;
		double inc = 1.0/ic.getMagnification();
		switch(key) {
			case KeyEvent.VK_UP: y2R-=inc; break;
			case KeyEvent.VK_DOWN: y2R+=inc; break;
			case KeyEvent.VK_LEFT: x2R-=inc; break;
			case KeyEvent.VK_RIGHT: x2R+=inc; break;
		}
		grow(screenXD(x+x2R), screenYD(y+y2R));
		notifyListeners(RoiListener.MOVED);
		showStatus();
	}

	/** Always returns true. */
	public boolean subPixelResolution() {
		return true;
	}

	public void setLocation(int x, int y) {
		setLocation((double)x, (double)y);
	}

	/** Sets the x coordinate of the leftmost and y coordinate of the topmost end point */
	public void setLocation(double x, double y) {
		updateCoordinates(x+x1R, y+y1R, x+x2R, y+y2R);
	}

	public FloatPolygon getRotationCenter() {
		double xcenter = x1d + (x2d-x1d)/2.0;
		double ycenter = y1d + (y2d-y1d)/2.0;
		FloatPolygon p = new FloatPolygon();
		p.addPoint(xcenter,ycenter);
		return p;
	}

	/**
	 * Dedicated point iterator for thin lines.
	 * The iterator is based on (an improved version of) the algorithm used by
	 * the original method {@code ImageProcessor.getLine(double, double, double, double)}.
	 * Improvements are (a) that the endpoint is drawn too and (b) every line
	 * point is visited only once, duplicates are skipped.
	 *
	 * Author: Wilhelm Burger (04/2017)
	*/
	public static class PointIterator implements Iterator<Point> {
		private double x1, y1;
		private final int n;
		private final double xinc, yinc;
		private double x, y;
		private int u, v;
		private int u_prev, v_prev;
		private int i;

		public PointIterator(Line line) {
			this(line.x1d, line.y1d, line.x2d, line.y2d);
		}

		public PointIterator(double x1, double y1, double x2, double y2) {
			this.x1 = x1;
			this.y1 = y1;
			double dx = x2 - x1;
			double dy = y2 - y1;
			this.n = (int) Math.ceil(Math.sqrt(dx * dx + dy * dy));
			this.xinc = dx / n;
			this.yinc = dy / n;
			x = x1;
			y = y1;
			u = (int) Math.round(x - 0.5);
			v = (int) Math.round(y - 0.5);
			u_prev = Integer.MIN_VALUE;
			v_prev = Integer.MIN_VALUE;
			i = 0;
		}

		@Override
		public boolean hasNext() {
			return i <= n;	// needs to be '<=' to include last segment (point)!
		}

		@Override
		public Point next() {
			if (i > n) throw new NoSuchElementException();
			Point p = new Point(u, v);	// the current (next) point
			moveToNext();
			return p;
		}

		// move to next point by skipping duplicate points
		private void moveToNext() {
			do {
				i = i + 1;
				x = x1 + i * xinc;
				y = y1 + i * yinc;
				u_prev = u;
				v_prev = v;
				u = (int) Math.round(x - 0.5);
				v = (int) Math.round(y - 0.5);
			} while (i <= n && u == u_prev && v == v_prev);
		}

		@Override
		public void remove() {
			throw new UnsupportedOperationException();
		}
	}

	@Override
	public Iterator<Point> iterator() {
		if (getStrokeWidth() <= 1.0)
			return new PointIterator(this);	// use the specific thin-line iterator
		else
			return super.iterator();	// fall back on Roi's iterator
	}

}