Merge "Fix error in inserting dual inline components"

[simantics/3d.git] / org.simantics.plant3d / src / org / simantics / plant3d / scenegraph / controlpoint / PipeControlPoint.java

package org.simantics.plant3d.scenegraph.controlpoint;

import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collection;
import java.util.List;
import java.util.Objects;

import javax.vecmath.AxisAngle4d;
import javax.vecmath.Matrix3d;
import javax.vecmath.Point3d;
import javax.vecmath.Quat4d;
import javax.vecmath.Tuple3d;
import javax.vecmath.Vector3d;

import org.simantics.g3d.math.MathTools;
import org.simantics.g3d.property.annotations.GetPropertyValue;
import org.simantics.g3d.scenegraph.G3DNode;
import org.simantics.g3d.scenegraph.base.INode;
import org.simantics.plant3d.scenegraph.IP3DNode;
import org.simantics.plant3d.scenegraph.Nozzle;
import org.simantics.plant3d.scenegraph.P3DRootNode;
import org.simantics.plant3d.scenegraph.PipeRun;
import org.simantics.plant3d.scenegraph.PipelineComponent;

import vtk.vtkRenderer;


public class PipeControlPoint extends G3DNode implements IP3DNode {

        private static boolean DEBUG = false;

        public enum PointType{INLINE,TURN,END};
        public enum Direction{NEXT,PREVIOUS};
        public enum PositionType {SPLIT,NEXT,PREVIOUS,PORT}

        private PipelineComponent component;

        private PointType type;
        private boolean isFixed = true;        // In-line: fixed-length Turn: fixed-angle
        private boolean isMod = false;         // Can user modify fixed value manually 
        private boolean isRotate = false;      // rotates around path leg axis.
        private boolean isReverse = false;     // definition direction can be swapped
        private boolean isDeletable = true;    // can be removed by rules
        private boolean isSizeChange = false;  // changes size of the pipe. The next control point / component is on different PipeRun
        private boolean isSub = false;         // child point for offset / size change

        private boolean disposed = false;
        
        public PipeControlPoint(PipelineComponent component) {
                this.component = component;
                if (component.getPipeRun() != null)
                        component.getPipeRun().addChild(this);

        }

        public PipeControlPoint(PipelineComponent component, PipeRun piperun) {
                this.component = component;
                piperun.addChild(this);
        }

        @Override
        public void update(vtkRenderer ren) {
                try {
                        PipingRules.requestUpdate(this);
                } catch (Exception e) {
                        e.printStackTrace();
                }

        }

        public PipeRun getPipeRun() {
                return (PipeRun)getParent();
        }

        public PipelineComponent getPipelineComponent() {
                return component;
        }

        public PointType getType() {
                return type;
        }

        public void setType(PointType type) {
                this.type = type;
        }

        @GetPropertyValue(name="Fixed",tabId="Debug",value="fixed")
        public boolean isFixed() {
                return isFixed;
        }

        public void setFixed(boolean fixed) {
                this.isFixed = fixed;
        }
        
        @GetPropertyValue(name="Mod",tabId="Debug",value="mod")
        public boolean isMod() {
        return isMod;
    }
    
    public void setMod(boolean isMod) {
        this.isMod = isMod;
    }

        @GetPropertyValue(name="Rotate",tabId="Debug",value="rotate")
        public boolean isRotate() {
                return isRotate;
        }

        public void setRotate(boolean rotate) {
                this.isRotate = rotate;
        }

        @GetPropertyValue(name="Reverse",tabId="Debug",value="reverse")
        public boolean isReverse() {
                return isReverse;
        }

        public void setReverse(boolean reverse) {
                this.isReverse = reverse;
        }

        public void setSub(boolean sub) {
                this.isSub = sub;
        }

        @GetPropertyValue(name="Deletable",tabId="Debug",value="deletable")
        public boolean isDeletable() {
                return isDeletable;
        }

        public void setDeletable(boolean deletable) {
                this.isDeletable = deletable;
        }

        public boolean isPathLegEnd() {
                return type != PointType.INLINE;
        }

        public boolean isEnd() {
                return type == PointType.END;
        }

        public boolean isTurn() {
                return type == PointType.TURN;
        }

        public boolean isInline() {
                return type == PointType.INLINE;
        }
        
        public boolean asPathLegEnd() {
            // Ends and Turns are path leg ends by default, but also unconnected inline are path leg ends.
            return isPathLegEnd() || getNext() == null || getPrevious() == null;
        }

        /**
         * True for end components, if control point defines absolute position direction, which rules cannot modify. 
         * This is typical for nozzles.
         * @return
         */
        public boolean isDirected() {
                return isFixed && isEnd();
        }

        /**
     * True for end components, if control is opposite to directed, and rules can modify position and orientation.
     * This is typical for caps, and other end components.
     * @return
     */
        public boolean isNonDirected() {
                return !isFixed && isEnd();
        }

        public boolean isVariableLength() {
                return !isFixed && isInline();
        }
        
        /**
         * Fixed length in-line component is such that piping rules cannot modify the length.
         * @return
         */
        public boolean isFixedLength() {
        return isFixed && isInline();
    }

        public boolean isVariableAngle() {
                return !isFixed && isTurn();
        }
        
        /**
         * Fixed angle turn component is such that piping rules cannot modify the angle.
         * @return
         */
        public boolean isFixedAngle() {
        return isFixed && isTurn();
    }
        
        /**
         * Does the turn behave like fixed angle?
         * For variable angle turns, the turn angle is defined by connected components, and without them, we must handle the component as fixed angle. 
         * @return
         */
        public boolean asFixedAngle() {
        return isTurn() && (isFixed || next == null || previous == null);
    }

        public boolean isBranchEnd() {
                return isDeletable && isEnd();
        }

        public boolean isOffset() {
                return offset != null;
        }

        public boolean isDualSub() {
                return parent != null && isSub;
        }

        public boolean isDualInline() {
                return children.size() == 1 && children.get(0).isDualSub();
        }

        public boolean isAxial() {
                return isInline() && !isDualInline();
        }

        public boolean isSizeChange() {
                return isSizeChange;
                //              if (children.size() == 0)
                //                      return false;
                //              if (!isDualInline())
                //                      return false;
                //              return getPipeRun() != children.get(0).getPipeRun();
        }

        public void setSizeChange(boolean isSizeChange) {
                this.isSizeChange = isSizeChange;
        }


        private PipeControlPoint next;
        private PipeControlPoint previous;

        public PipeControlPoint getNext() {
                return next;
        }

        public PipeControlPoint getPrevious() {
                return previous;
        }

        public void setNext(PipeControlPoint next) {
            if (isSub) {
                getParentPoint().setNext(next);
                return;
            }
            if (next != null && next.isDualSub())
                next = next.parent;
            if (_setNext(next)) {
                for (PipeControlPoint pcp : children) {
                if (pcp.isSub)
                    pcp._setNext(next);
            }
                updateSubPoint();
            }
        }
        
        public void setPrevious(PipeControlPoint prev) {
        if (isSub) {
            getParentPoint().setPrevious(prev);
            return;
        }
        if (prev != null && prev.isDualInline())
            prev = prev.children.get(0);
        if (_setPrevious(prev)) {
            for (PipeControlPoint pcp : children) {
                if (pcp.isSub)
                    pcp._setPrevious(prev);
            }
            updateSubPoint();
        }
    }
        
        protected boolean _setNext(PipeControlPoint next) {
                if (isEnd() && previous != null && next != null)
                        throw new RuntimeException("End control points are allowed to have only one connection");
                if (next == this)
                        throw new RuntimeException("Cannot connect to self");
                if (this.next == next)
                        return false;
                if (DEBUG) System.out.println(this + " next " + next);
                if (next == null && isVariableAngle() && previous != null && !isRemoved()) {
                    convertVariableAngleToFixed(Direction.NEXT);
                }
                this.next = next;
                if (component != null) {
                        if (parent == null || isSub)
                                component.setNext(next != null ? next.component : null);
                        else
                                component.setBranch0(next != null ? next.component : null);
                        
                }
                return true;
        }

        protected boolean _setPrevious(PipeControlPoint previous) {
                if (isEnd() && next != null && previous != null)
                        throw new RuntimeException("End control points are allowed to have only one connection");
                if (previous == this)
                        throw new RuntimeException("Cannot connect to self");
                if (this.previous == previous)
                        return false;
                if (DEBUG) System.out.println(this + " previous " + previous);
                if (previous == null && isVariableAngle() && next != null && !isRemoved()) {
            convertVariableAngleToFixed(Direction.PREVIOUS);
        }
                this.previous = previous;
                if (component != null) {
                        if (parent == null || isSub)
                                component.setPrevious(previous != null ? previous.component : null);
                        else
                                component.setBranch0(previous != null ? previous.component : null);
                        updateSubPoint();
                }
                return true;
        }
        
        private void convertVariableAngleToFixed(Direction direction) {
            // We are removing reference, which transforms variable angle to fixed angle.
        // Since fixed angle is defined differently, we need to calculate fixed angle parameters based on current data
        // We need to calculate turnAngle and rotationAngle
            Vector3d dirOut = getPathLegDirection(direction == Direction.NEXT ? Direction.NEXT : Direction.PREVIOUS);
        Vector3d dir = getPathLegDirection(direction == Direction.NEXT ? Direction.PREVIOUS : Direction.NEXT);
        if (dir == null || dirOut == null)
            return;
        dir.negate();
        double angle = dir.angle(dirOut);
        //super._setNext(null);
        if (direction == Direction.NEXT)
            next = null;
        else
            previous = null;
        setRotationAngle(0.0);
        setReversed(direction == Direction.NEXT ? false : true);
        Vector3d dirOutN = getPathLegDirection(direction == Direction.NEXT ? Direction.NEXT : Direction.PREVIOUS);
        dirOutN.normalize();
        AxisAngle4d aa = new AxisAngle4d();
        if (MathTools.createRotation(dirOutN, dirOut, dir, aa)) {
            setRotationAngle(aa.angle);
            setTurnAngle(angle);
            if (DEBUG) System.out.println("convertToFixed " + dir + " " + dirOut + " " +dirOutN + " " +angle + " "+ aa.angle);
        }
        }

        public PipeControlPoint parent;
        public List<PipeControlPoint> children = new ArrayList<PipeControlPoint>();

        public List<PipeControlPoint> getChildPoints() {
                return children;
        }

        public PipeControlPoint getParentPoint() {
                return parent;
        }


        private double length;
        private Double turnAngle;
        private Vector3d turnAxis;

        private Double offset;
        private Double rotationAngle;
        private Boolean reversed;

        @GetPropertyValue(name="Length",tabId="Debug",value="length")
        public double getLength() {
                return length;
        }

        public void setLength(double l) {
                if (this.length == l)
                        return;
                if (Double.isInfinite(l) || Double.isNaN(l))
                        return;
                if (Math.abs(this.length-l) < MathTools.NEAR_ZERO)
                        return;
                this.length = l;
                firePropertyChanged("length");
                if (isDualInline())
                    getDualSub().setLength(l);
        }

        @GetPropertyValue(name="Turn Angle",tabId="Debug",value="turnAngle")
        public Double getTurnAngle() {
                return turnAngle;
        }

        @GetPropertyValue(name="Turn Axis",tabId="Debug",value="turnAxis")
        public Vector3d getTurnAxis() {
                return turnAxis;
        }

        @GetPropertyValue(name="Offset",tabId="Debug",value="offset")
        public Double getOffset() {
                return offset;
        }

        @GetPropertyValue(name="Rotation Angle",tabId="Debug",value="rotationAngle")
        public Double getRotationAngle() {
            if (isRotate || asFixedAngle())
                return rotationAngle;
            return null;
        }

        @GetPropertyValue(name="Reversed",tabId="Debug",value="reversed")
        public Boolean getReversed() {
                return reversed;
        }

        public boolean _getReversed() {
                if (reversed == null)
                        return false;
                return reversed;
        }

        public void setTurnAngle(Double turnAngle) {
                if (turnAngle == null || Double.isInfinite(turnAngle) || Double.isNaN(turnAngle)) {
                        return;
                }
                if (this.turnAngle != null && Math.abs(this.turnAngle-turnAngle) < MathTools.NEAR_ZERO)
                        return;
                if (Objects.equals(this.turnAngle, turnAngle))
                        return;
                this.turnAngle = turnAngle;
                firePropertyChanged("turnAngle");
        }

        public void setTurnAxis(Vector3d turnAxis) {
                if (this.turnAxis != null && MathTools.equals(turnAxis, this.turnAxis))
                        return;
                this.turnAxis = turnAxis;
                firePropertyChanged("turnAxis");
        }

        public void setOffset(Double offset) {
                if (Double.isInfinite(offset) || Double.isNaN(offset)) {
                        return;
                }
                if (this.offset != null && Math.abs(this.offset-offset) < MathTools.NEAR_ZERO)
                        return;
                if (Objects.equals(this.offset, offset))
                        return;
                this.offset = offset;
                firePropertyChanged("offset");
        }

        public void setRotationAngle(Double rotationAngle) {
                if (Double.isInfinite(rotationAngle) || Double.isNaN(rotationAngle)) {
                        return;
                }
                if (this.rotationAngle != null && Math.abs(this.rotationAngle-rotationAngle) < MathTools.NEAR_ZERO)
                        return;
                if (Objects.equals(this.rotationAngle, rotationAngle))
                        return;
                this.rotationAngle = rotationAngle;
                firePropertyChanged("rotationAngle");
        }

        public void setReversed(Boolean reversed) {
                if (this.reversed == reversed)
                        return;
                this.reversed = reversed;
                firePropertyChanged("reversed");
        }

        public Vector3d getSizeChangeOffsetVector(Vector3d dir) {
                Quat4d q;
                if (rotationAngle == null)
                        q = getControlPointOrientationQuat(dir, 0.0);
                else
                        q = getControlPointOrientationQuat(dir, rotationAngle);
                Vector3d v = new Vector3d(0.0,offset,0.0);
                Vector3d offset = new Vector3d();
                MathTools.rotate(q, v, offset);
                return offset;
        }

        public Vector3d getSizeChangeOffsetVector() {
                Quat4d q;
                if (rotationAngle == null)
                        q = getControlPointOrientationQuat(0.0);
                else
                        q = getControlPointOrientationQuat(rotationAngle);
                Vector3d v = new Vector3d(0.0,offset,0.0);
                Vector3d offset = new Vector3d();
                MathTools.rotate(q, v, offset);
                return offset;
        }

        @GetPropertyValue(name="Next",tabId="Debug",value="next")
        private String getNextString() {
                if (next == null)
                        return null;
                return next.toString();
        }

        @GetPropertyValue(name="Previous",tabId="Debug",value="previous")
        private String getPrevString() {
                if (previous == null)
                        return null;
                return previous.toString();
        }

        @GetPropertyValue(name="Sub",tabId="Debug",value="sub")
        private String getSubString() {
                if (children.size() == 0)
                        return "";
                return Arrays.toString(children.toArray());
        }

        @GetPropertyValue(name="Type",tabId="Debug",value="type")
        public String getTypeString() {
                return type.name();
        }

        public Vector3d getPathLegEndpointVector() {
                PipeControlPoint a = findPreviousEnd();
                PipeControlPoint b = findNextEnd();
                
                if (a == null || b == null) {
                        return getPathLegDirection();
                }
                
                Vector3d p1 = a.getWorldPosition();
                Vector3d p2 = b.getWorldPosition();
                p2.sub(p1);
                double l = p2.length();
                if (l != 0.0) {
                        p2.scale(1.0 / l);
                        return p2;
                }
                else {
                        return getPathLegDirection();
                }
        }

        public Vector3d getPathLegDirection() {
                if (turnAxis == null) {
                        return getPathLegDirection(Direction.NEXT);
                } else {
                        Vector3d dir = getPathLegDirection(Direction.PREVIOUS);
                        if (dir != null) dir.negate();
                        return dir;
                }
        }
        
        public Quat4d getControlPointOrientationQuat(double angle) {
                Vector3d dir = getPathLegDirection();
                if (turnAxis == null) {
                        return getControlPointOrientationQuat(dir, angle);
                } else {
                        return getControlPointOrientationQuat(dir, turnAxis, angle);
                }
        }
        
        public Quat4d getControlPointOrientationQuat(Vector3d dir, double angle, boolean reversed) {
            if (turnAxis == null) {
            if (dir.lengthSquared() > MathTools.NEAR_ZERO)
                dir.normalize();
            Quat4d q =  getControlPointOrientationQuat(dir, angle);
            if (reversed) {
                Quat4d q2 = new Quat4d();
                q2.set(new AxisAngle4d(MathTools.Y_AXIS, Math.PI));
                q.mulInverse(q2);
            }
            return q;
        } else {
            if (dir.lengthSquared() > MathTools.NEAR_ZERO)
                dir.normalize();
            return getControlPointOrientationQuat(dir, turnAxis, angle);
        }
        }

        public Quat4d getControlPointOrientationQuat(double angle, boolean reversed) {
                Vector3d dir = getPathLegDirection();
                return getControlPointOrientationQuat(dir, angle, reversed);
        }

        public Quat4d getControlPointOrientationQuat(Vector3d dir, double angle) {
                if (dir == null || dir.lengthSquared() < MathTools.NEAR_ZERO)
                        return MathTools.getIdentityQuat();

                final P3DRootNode root = getRoot();
                Vector3d up = root != null ? new Vector3d(root.getUpVector()) : new Vector3d(0.0, 1.0, 0.0);
                final Vector3d legDir = getPathLegEndpointVector();
                double a = up.angle(legDir);
                if (a < 0.1 || (Math.PI - a) < 0.1) {
                        // Rotate components
                        up.set(up.getY(), up.getZ(), up.getX());
                }
                
                // Project up vector into a normal of the leg direction before applying to 'dir'
                MathTools.mad(up, legDir, -legDir.dot(up)/legDir.lengthSquared());
                up.normalize();

                return getControlPointOrientationQuat(dir, up, angle);
        }

        public P3DRootNode getRoot() {
                INode n = getParent();
                while (n != null && !(n instanceof P3DRootNode))
                        n = n.getParent();
                return (P3DRootNode) n;
        }

        public static Quat4d getControlPointOrientationQuat(Vector3d dir, Vector3d up,  double angle) {
                if (dir == null || dir.lengthSquared() < MathTools.NEAR_ZERO)
                        return MathTools.getIdentityQuat();

                final Vector3d front = new Vector3d(1.0,0.0,0.0);

                Quat4d q1 = new Quat4d();


                Vector3d right = new Vector3d();
                
                up = new Vector3d(up);
                right.cross(dir, up);
                up.cross(right, dir);
                right.normalize();
                up.normalize();

                Matrix3d m = new Matrix3d();
                m.m00 = dir.x;
                m.m10 = dir.y;
                m.m20 = dir.z;
                m.m01 = up.x;
                m.m11 = up.y;
                m.m21 = up.z;
                m.m02 = right.x;
                m.m12 = right.y;
                m.m22 = right.z;

                //q1.set(m); MathTools contains more stable conversion
                MathTools.getQuat(m, q1);

                //                      if (DEBUG) System.out.println("PipingTools.getPipeComponentOrientationQuat() " + dir+ " " + up + " " + right);

                Quat4d q2 = new Quat4d();
                q2.set(new AxisAngle4d(front, angle));
                q1.mul(q2);
                return q1;
        }

        public void insert(PipeControlPoint previous, PipeControlPoint next) {
                // inserting an offsetpoint is error, 
                if (isDualSub())
                        throw new RuntimeException("Dual sub points cannot be inserted.");
                // size change control point cannot be inserted this way, because it ends PipeRun
//              if (isSizeChange())
//                      throw new RuntimeException("Size change points cannot be inserted.");
                PipeRun piperun = previous.getPipeRun();
                // and just to make sure that control point structure is not corrupted
                if (getPipeRun() != null) {
                        if (piperun != getPipeRun() || piperun != next.getPipeRun())
                                throw new RuntimeException("All controls points must be located on the same pipe run");
                } else {
                        piperun.addChild(this);
                }

                // insert new BranchControlPoint between straight's control points
                PipeControlPoint previousNext = previous.getNext();
                PipeControlPoint previousPrevious = previous.getPrevious();

                PipeControlPoint offsetCP = null;
                if (isOffset()) {
                        offsetCP = getDualSub();
                }
                if (previousNext != null && previousNext == next) {
                        if (previous.isDualInline()) {
                                throw new RuntimeException();
                        }
                        if (next.isDualSub()) {
                                throw new RuntimeException();
                        }
                        previous.setNext(this);
                        this.setPrevious(previous);
                        if (previous.isDualSub()) {
                                previous.getParentPoint().setNext(this);
                        }
                        this.setNext(next);

                        if (offsetCP == null) {
                                next.setPrevious(this);
                        } else {
                                next.setPrevious(offsetCP);
                                offsetCP.setNext(next);
                                offsetCP.setPrevious(previous);
                        }

                        if (next.isDualInline()) {
                                next.getDualSub().setPrevious(this);
                        }
                } else if (previousPrevious != null && previousPrevious == next) {
                        // control point were given in reverse order 
                        if (next.isDualInline())
                                throw new RuntimeException();
                        if (previous.isDualSub())
                                throw new RuntimeException();

                        this.setNext(previous);
                        if (offsetCP == null) {
                                previous.setNext(this);
                        } else {
                                previous.setPrevious(offsetCP);
                                offsetCP.setNext(previous);
                                offsetCP.setPrevious(next);
                        }
                        if (previous.isDualInline()) {
                                previous.getDualSub().setPrevious(this);
                        }
                        this.setPrevious(next);
                        next.setNext(this);
                        if (next.isDualSub()) {
                                next.getParentPoint().setNext(this);
                        }

                } else {
                        throw new RuntimeException();
                }       

                PipingRules.validate(piperun);
        }



        public void insert(PipeControlPoint pcp, Direction direction) {
                if (isDualSub())
                        throw new RuntimeException();
                if (direction == Direction.NEXT) {
                        // if direction is next, user must have given OffsetPoint
                        if (pcp.isDualInline())
                                throw new RuntimeException();
                        // basic next/prev links
                        pcp.setNext(this);
                        this.setPrevious(pcp);
                        // and last take care of sizechange / offset points
                        if (pcp.isDualSub()) {
                                pcp.getParentPoint().setNext(this);
                        }
                } else {
                        // if direction is previous, user must have given sizechange
                        if (pcp.isDualSub())
                                throw new RuntimeException();
                        // previous direction is more complicated, since if newCP is SizeChangeControlPoint,
                        // we must link pcp to newCP's OffsetPoint
                        PipeControlPoint nocp = null;
                        if (isDualInline()) {
                                nocp = getDualSub();
                                nocp.setNext(pcp);
                        }
                        if (nocp == null) {
                                pcp.setPrevious(this);
                        } else {
                                pcp.setPrevious(nocp);
                        }
                        this.setNext(pcp);
                        if (pcp.isDualInline()) {
                                PipeControlPoint ocp = pcp.getDualSub();
                                if (nocp == null)
                                        ocp.setPrevious(this);
                                else
                                        ocp.setPrevious(nocp);
                        }

                }
                PipingRules.validate(getPipeRun());
        }

        public Vector3d getDirectedControlPointDirection() {
                assert (isDirected());
                Vector3d dir = new Vector3d();
                MathTools.rotate(getWorldOrientation(), new Vector3d(1.0, 0.0, 0.0), dir);
                dir.normalize();
                return dir;
        }
        
        /**
         * Returns direction vector pointing towards an adjacent component for
         * directed control points or turn control points with one open end. 
         * 
         * Always returns an outwards pointing vector.
         * 
         * For any other type of component, the return value is null.
         * 
         * For turn components this only return a non-null value for the unconnected
         * end of the component. 
         * 
         * @param direction
         * @return normalized vector, or null
         */
        public Vector3d getDirection(Direction direction) {
        if (isDirected())
            return getDirectedControlPointDirection();
        if (isTurn() && asFixedAngle()) {
            if (direction == Direction.NEXT) {
                if (previous != null) {
                    PipeControlPoint pcp = this;
                    Vector3d dir = new Vector3d();
                    dir.sub(pcp.getWorldPosition(),previous.getWorldPosition());
                    if (dir.lengthSquared() > MathTools.NEAR_ZERO)
                        dir.normalize();
                    else
                        return null;
                    Quat4d q = getControlPointOrientationQuat(dir, pcp.getRotationAngle() != null ? pcp.getRotationAngle() : 0.0);
                    AxisAngle4d aa = new AxisAngle4d(MathTools.Y_AXIS,pcp.getTurnAngle() == null ? 0.0 : pcp.getTurnAngle());
                    Quat4d q2 = MathTools.getQuat(aa);
                    Vector3d v = new Vector3d(1.,0.,0.);
                    Vector3d offset = new Vector3d();
                    MathTools.rotate(q2, v, offset);
                    MathTools.rotate(q, offset, dir);
                    dir.normalize();
                    return dir;
                }
            } else {
                if (next != null) {
                    PipeControlPoint pcp = this;
                    Vector3d dir = new Vector3d();
                    dir.sub(next.getWorldPosition(),pcp.getWorldPosition());
                    if (dir.lengthSquared() > MathTools.NEAR_ZERO)
                        dir.normalize();
                    else
                        return null;
                    Quat4d q = getControlPointOrientationQuat(dir, pcp.getRotationAngle() != null ? pcp.getRotationAngle() : 0.0);
                    AxisAngle4d aa = new AxisAngle4d(MathTools.Y_AXIS,pcp.getTurnAngle() == null ? 0.0 : pcp.getTurnAngle());
                    Quat4d q2 = MathTools.getQuat(aa);
                    Vector3d v = new Vector3d(1.,0.,0.);
                    Vector3d offset = new Vector3d();
                    MathTools.rotate(q2, v, offset);
                    MathTools.rotate(q, offset, dir);
                    dir.negate();
                    dir.normalize();
                    return dir;
                }
            }
        }
        return null;
    }

        /**
         * Returns path leg direction of the control point.
         * 
         * This method differs from getDirection by also returning inward pointing vectors for directed control points.
         * 
         * @param direction
         * @return
         */
        public Vector3d getPathLegDirection(Direction direction) {
                if (direction == Direction.NEXT) {
                        return getPathLegDirectionNext();
                } else {
                        return getPathLegDirectionPrevious();
                }
        }

        public Vector3d getPathLegDirectionPrevious() {
                if (previous != null) {
                        PipeControlPoint pcp = this;
                        if (isDualSub()) 
                                pcp = getParentPoint();
                        Vector3d v = new Vector3d();
                        v.sub(previous.getWorldPosition(),pcp.getWorldPosition());
                        if (v.lengthSquared() > MathTools.NEAR_ZERO)
                        v.normalize();
                    else
                        return null;
                        return v;
                } else if (isDirected()) {
                        Vector3d v = getDirectedControlPointDirection();
                        v.negate();
                        return v;
                } else if (next == null)  {
                        throw new RuntimeException("Cannot calculate path leg direction for unconnected control point " + this);
                } else if (isVariableAngle() && !asFixedAngle()) {
                        throw new RuntimeException("Cannot calculate path leg direction for unconnected variable angle control point " + this);
                } else if (isInline() || isEnd()) {
                        Vector3d v = getPathLegDirectionNext();
                        if (v != null) v.negate();
                        return v;
                } else if (isTurn() && asFixedAngle() && _getReversed()) {
                        return getDirection(Direction.PREVIOUS);
                } else {
                        throw new RuntimeException("Missing implementation " + this);
                }
        }

        public Vector3d getPathLegDirectionNext() {
                if (next != null) {
                        PipeControlPoint pcp = this;
                        if (pcp.isDualInline()) {
                                pcp = pcp.getDualSub();
                        }
                        Vector3d v = new Vector3d();
                        v.sub(next.getWorldPosition(),pcp.getWorldPosition());
                        if (v.lengthSquared() > MathTools.NEAR_ZERO)
                        v.normalize();
                    else
                        return null;
                        return v;
                } else if (isDirected()) {
                        return getDirectedControlPointDirection();
                } else if (previous == null) {
                        throw new RuntimeException("Cannot calculate path leg direction for unconnected control point " + this);
                } else if (isVariableAngle() && !asFixedAngle()) {
                        throw new RuntimeException("Cannot calculate path leg direction for unconnected variable angle control point " + this);
                } else if (isInline() || isEnd()) {
                        Vector3d v = getPathLegDirectionPrevious();
                        if (v != null) v.negate();
                        return v;
                } else if (isTurn() && asFixedAngle() && !_getReversed()) {
                        return getDirection(Direction.NEXT);
                } else {
                        throw new RuntimeException("Missing implementation " + this);
                }
        }

        public void getInlineControlPointEnds(Tuple3d p1, Tuple3d p2) {
                assert (isInline());

                PipeControlPoint sub = isAxial() ? this : getDualSub();
                Vector3d pos = getWorldPosition(), pos2 = sub == this ? pos : sub.getWorldPosition();
                Vector3d dir = sub.getInlineDir();
                
                dir.scale(length * 0.5);
                p1.set(pos);
                p2.set(pos2);
                p1.sub(dir);
                p2.add(dir);
        }

        public void getControlPointEnds(Tuple3d p1, Tuple3d p2) {
                PipeControlPoint sub = isAxial() || isDirected() || isTurn() ? this : getChildPoints().get(0);
                Vector3d pos = getWorldPosition(), pos2 = sub == this ? pos : sub.getWorldPosition();
                
                Vector3d dir1;
                Vector3d dir2;
                if (isInline()) {
                        dir2 = getInlineDir();
                        dir2.scale(length * 0.5);
                        dir1 = new Vector3d(dir2);
                        dir1.negate();
                } else {
                        dir1 = getPathLegDirection(Direction.PREVIOUS);
                        dir2 = sub.getPathLegDirection(Direction.NEXT);
                        dir1.scale(length);
                        dir2.scale(length);
                }
                p1.set(pos);
                p2.set(pos2);
                p1.add(dir1);
                p2.add(dir2);
        }

        /**
         * Get both path leg directions, with (0,0,0) if no connection exists. The returned vectors are not normalized.
         * 
         * @param v1  Set to the direction towards the previous control point on output
         * @param v2  Set to the direction towards the next control point on output
         */
        public void getEndDirections(Tuple3d v1, Tuple3d v2) {
                PipeControlPoint sub = isAxial() ? this : getDualSub();
                
                Vector3d dir1 = getPathLegDirection(Direction.PREVIOUS);
                Vector3d dir2 = sub.getPathLegDirection(Direction.NEXT);
                
                if (dir1 != null)
                        v1.set(dir1);
                else
                        v1.set(0,0,0);
                
                if (dir2 != null)
                        v2.set(dir2);
                else
                        v2.set(0,0,0);
        }

        public void getInlineControlPointEnds(Tuple3d p1, Tuple3d p2, Vector3d dir) {
                assert (isInline());

                Vector3d pos = getWorldPosition();
                dir.set(getInlineDir());
                dir.normalize();
                dir.scale(length * 0.5);
                p1.set(pos);
                p2.set(pos);
                p1.sub(dir);
                p2.add(dir);
        }

        public void getInlineControlPointEnds(Tuple3d center, Tuple3d p1, Tuple3d p2, Vector3d dir) {
                assert (isInline());

                Vector3d pos = getWorldPosition();
                center.set(pos);
                dir.set(getInlineDir());
                dir.normalize();
                dir.scale(length * 0.5);
                p1.set(pos);
                p2.set(pos);
                p1.sub(dir);
                p2.add(dir);
        }

        public Vector3d getInlineDir() {
                Vector3d dir = getPathLegDirection(Direction.NEXT);
                if (dir == null) {
                        dir = getPathLegDirection(Direction.PREVIOUS);
                        if (dir != null) {
                                // Use reverse direction
                                dir.scale(-1.0);
                        } else {
                                // Control point is not connected at all, use current orientation
                                dir = new Vector3d(1,0,0);
                                MathTools.rotate(getWorldOrientation(), dir, dir);
                        }
                }
                return dir;
        }

        public double getInlineLength() {
                if (type == PointType.TURN)
                        return length;
                else if (type == PointType.INLINE)
                        return length * 0.5;
                return 0;
        }

        /**
         * Return the position indicated by the argument. If the indicated direction is not connected, the
         * control point's wolrd position is returned instead.
         * 
         * @param type  A selector for the position to be returned
         * @return  The selected position
         */
        public Vector3d getRealPosition(PositionType type) {
                Vector3d pos = getWorldPosition();
                switch (type) {
                case NEXT: {
                        double length = getInlineLength();
                        Vector3d dir;
                        if (isInline()) {
                                dir = getInlineDir();
                        } else {
                                dir = getPathLegDirection(Direction.NEXT);
                        }
                        dir.scale(length);
                        pos.add(dir);
                        break;
                }
                case PREVIOUS: {
                        double length = getInlineLength();
                        Vector3d dir;
                        if (isInline()) {
                                dir = getInlineDir();
                                dir.negate();
                        } else {
                                dir = getPathLegDirection(Direction.PREVIOUS);
                        }
                        dir.scale(length);
                        pos.add(dir);
                        break;
                }
                case PORT:
                        // IEntity portDir = pcp.getSingleRelatedObject(ProcessResource.plant3Dresource.HasDirection);
                        // TODO : how we calculated needed space for a port; does it has an offset from control point's position or not?
                        break;
                case SPLIT:
                        // do nothing
                        break;

                }
                return pos;
        }

        public void getInlineMovement(Tuple3d start, Tuple3d end) {
                // FIXME : check type of neighbor components and allow movement on top of variable length components,
                //         find proper range for movement (pcp's position is not)
                PipeControlPoint p = previous.getPrevious();
                PipeControlPoint n = next.getNext();
                start.set(p.getWorldPosition());
                end.set(n.getWorldPosition());
        }

        public PipeControlPoint findNextEnd() {
                ArrayList<PipeControlPoint> t = new ArrayList<PipeControlPoint>();
                return findNextEnd( t);
        }

        public PipeControlPoint findPreviousEnd() {
                ArrayList<PipeControlPoint> t = new ArrayList<PipeControlPoint>();
                return findPreviousEnd(t);
        }

        public PipeControlPoint findNextEnd(List<PipeControlPoint> nextList) {
                while (true) {
                        PipeControlPoint pcp = null;
                        PipeControlPoint p = null;
                        if (nextList.size() == 0)
                                p = this;

                        else
                                p = nextList.get(nextList.size() - 1);

                        pcp = p.getNext();
                        if (pcp == null) {
                                pcp = p;
                                if (nextList.size() > 0)
                                        nextList.remove(nextList.size() - 1);
                                //              if (DEBUG) System.out.println(" " + pcp.getResource() + " not full");
                                return pcp;
                                //break;
                        }
                        if (pcp.isPathLegEnd()) {
                                //if (DEBUG) System.out.println(" " + pcp.getResource());
                                return pcp;
                        } else {
                                nextList.add(pcp);
                                // if (DEBUG) System.out.print(" " + pcp.getResource());
                        }
                }
        }

        public PipeControlPoint findPreviousEnd(List<PipeControlPoint> prevList) {
                while (true) {
                        PipeControlPoint pcp = null;
                        PipeControlPoint p = null;
                        if (prevList.size() == 0)
                                p = this;

                        else
                                p = prevList.get(prevList.size() - 1);

                        pcp = p.getPrevious();
                        if (pcp == null) {
                                pcp = p;
                                if (prevList.size() > 0)
                                        prevList.remove(prevList.size() - 1);
                                //                              if (DEBUG) System.out.println(" " + pcp.getResource() + " not full");
                                return pcp;
                        }
                        if (pcp.isPathLegEnd()) {
                                //                              if (DEBUG)      System.out.println(" " + pcp.getResource());
                                return pcp;
                        } else {
                                prevList.add(pcp);
                                //                              if (DEBUG)System.out.print(" " + pcp.getResource());
                        }
                }
        }
        
        public void _remove() {
            _remove(true);
        }
        
        
        public PipeControlPoint getDualSub() {
            if (isDualInline())
                return getChildPoints().get(0);
            else
                throw new IllegalStateException("Current control point is not dual inline");
        }
        

        public void _remove(boolean renconnect) {
            if (disposed)
                return;
                
            if (DEBUG) System.out.println(this + " Remove " + renconnect);

                if (getParentPoint() != null) {
                    getParentPoint()._remove(renconnect);
                    return;
                }
                PipeRun pipeRun = getPipeRun();
//              PipeRUn removal has been changed, so pipeRun may be null.
//              if (pipeRun == null)
//                      return;

                PipeControlPoint additionalRemove = null;
                if (!PipingRules.isEnabled()) {
                    component = null;
                        setPrevious(null);
                        setNext(null);
                } else {

                        PipeControlPoint currentPrev = previous;
                        PipeControlPoint currentNext = next;
                        if (currentNext == null && currentPrev == null) {
                                removeComponent();
                                if (pipeRun != null) {
                                    pipeRun.remChild(this);
                                    checkRemove(pipeRun);
                                }
                                return;
                        }
                        if (currentNext != null && currentPrev != null) {
                                boolean link = renconnect;
                                if (currentNext.isBranchEnd()) {
                                        link = false;
                                        currentNext.remove();
                                        currentNext = null;
                                        setNext(null);
                                }
                                if (currentPrev.isBranchEnd()) {
                                        link = false;
                                        currentPrev.remove();
                                        currentPrev = null;
                                        setPrevious(null);
                                }
                                if (link) {
                                    if (currentPrev.isDirected() && currentNext.isDirected())
                                        link = false;
                                    else if (this.isDualSub()) {
                                        throw new RuntimeException("_remove() is called for parent point, somehow got to child point. " + this);
                                    }
                                }
                                if (currentNext == null) {
                                        // Nothing to do
                                } else if (currentNext.isDualInline()) {
                                        PipeControlPoint sccp = currentNext;
                                        PipeControlPoint ocp = currentNext.getDualSub();
                                        if (ocp == null) {
                                                throw new RuntimeException("Removing PipeControlPoint " + this+ " structure damaged, no offset control point");
                                        }
                                        if (link) {
                                                sccp.setPrevious(currentPrev);
                                                //ocp.setPrevious(currentPrev);
                                                assert(ocp.getPrevious() == currentPrev);
                                        } else {
                                                sccp.setPrevious(null);
                                                //ocp.setPrevious(null);
                                                assert(ocp.getPrevious() == null);
                                        }
                                        setNext(null);
                                } else if (currentNext.isDualSub()) {
                                        throw new RuntimeException("Removing PipeControlPoint " + this + " structure damaged, next control point is offset control point");
                                } else if (currentNext.previous == this) {
                                        if (link) {
                                                currentNext.setPrevious(currentPrev);
                                        } else {
                                                currentNext.setPrevious(null);
                                        }
                                        setNext(null);
                                } else if (isDualInline()) {
                                    if (currentNext.previous != getDualSub()) {
                                        throw new RuntimeException("Removing PipeControlPoint "+ this+ " structure damaged");
                                    }
                                    if (link) {
                        currentNext.setPrevious(currentPrev);
                    } else {
                        currentNext.setPrevious(null);
                    }
                    setNext(null);
                                } else {
                                        throw new RuntimeException("Removing PipeControlPoint "+ this+ " structure damaged");
                                }
                                if (currentPrev == null) {
                                        // Nothing to do
                                } else if (currentPrev.isDualInline()) {
                                        throw new RuntimeException("Removing PipeControlPoint " + this + " structure damaged, previous control point is size change control point");
                                } else if (currentPrev.isDualSub()) {
                                        PipeControlPoint ocp = currentPrev;
                                        PipeControlPoint sccp = currentPrev.getParentPoint();
                                        if (sccp == null)
                                                throw new RuntimeException("Removing PipeControlPoint " + this + " structure damaged, no size change control point");
                                        if (link) {
                                                //ocp.setNext(currentNext);
                                                sccp.setNext(currentNext);
                                                assert(ocp.getNext() == currentNext);
                                        } else {
                                                //ocp.setNext(null);
                                                sccp.setNext(null);
                                                assert(ocp.getNext() == null);
                                        }
                                        setPrevious(null);
                                } else if (currentPrev.next == this) {
                                        if (link)
                                                currentPrev.setNext(currentNext);
                                        else
                                                currentPrev.setNext(null);

                                        setPrevious(null);
                                } else {
                                        throw new RuntimeException("Removing PipeControlPoint " + this + " structure damaged");
                                }
                                if (link) {
                                        if (currentNext.isVariableLength() && currentPrev.isVariableLength()) {
                                                // we have to join them into single variable length component.
                                                additionalRemove = currentPrev;
                                                // combine lengths and set the location of remaining control point to the center.
                                                Point3d ps = new Point3d();
                                                Point3d pe = new Point3d();
                                                Point3d ns = new Point3d();
                                                Point3d ne = new Point3d();
                                                currentPrev.getInlineControlPointEnds(ps, pe);
                                                currentNext.getInlineControlPointEnds(ns, ne);
                                                double l = currentPrev.getLength() + currentNext.getLength();
                                                Vector3d cp = new Vector3d();
                                                cp.add(ps, ne);
                                                cp.scale(0.5);
                                                currentNext.setLength(l);
                                                currentNext.setWorldPosition(cp);
                                        }
                                } else {
                                        // FIXME : pipe run must be split into two parts, since the control point structure is no more continuous. 
                                }
                        } else if (currentNext != null) {
                                if (currentNext.isDualInline()) {
                                        PipeControlPoint sccp = currentNext;
                                        PipeControlPoint ocp = currentNext.getDualSub();
                                        if (ocp == null) {
                                                throw new RuntimeException("Removing PipeControlPoint " + this+ " structure damaged, no offset control point");
                                        }
                                        sccp.setPrevious(null);
                                        assert(ocp.getPrevious() == null);
                                        //ocp.setPrevious(null);
                                } else if (currentNext.isDualSub()) {
                                        throw new RuntimeException("Removing PipeControlPoint " + this + " structure damaged, next control point is offset control point");
                                } else if (currentNext.previous == this) {
                                    currentNext.setPrevious(null);
                                }  else if (isDualInline()) {
                    if (currentNext.previous != getDualSub()) {
                        throw new RuntimeException("Removing PipeControlPoint "+ this+ " structure damaged");
                    }
                    currentNext.setPrevious(null);
                                } else {
                                        throw new RuntimeException("Removing PipeControlPoint "+ this+ " structure damaged");
                                }
                                setNext(null);
                        } else {  //(previous != null)
                                if(currentPrev.isDualInline()) {
                                        throw new RuntimeException("Removing PipeControlPoint " + this + " structure damaged, previous control point is size change control point");
                                } else if (currentPrev.isDualSub()) {
                                        PipeControlPoint ocp = currentPrev;
                                        PipeControlPoint sccp = currentPrev.getParentPoint();
                                        if (sccp == null) {
                                                throw new RuntimeException("Removing PipeControlPoint " + this + " structure damaged, no size change control point");
                                        }
                                        sccp.setNext(null);
                                        assert(ocp.getNext() == null);
                                } else if (currentPrev.next == this) {
                                    currentPrev.setNext(null);
                                } else {
                                        throw new RuntimeException("Removing PipeControlPoint "+ this+ " structure damaged");
                                }
                                setPrevious(null);
                        }
                        if (children.size() > 0 ) {
                                removeSubPoints();
                        } else if (parent!= null) {
                                removeParentPoint();
                        }

                }

                removeComponent();
                if (pipeRun != null) {
                pipeRun.remChild(this);
                checkRemove(pipeRun);
                if (PipingRules.isEnabled() && pipeRun.getParent() != null && pipeRun.getControlPoints().size() > 0)
                        PipingRules.validate(pipeRun);
                }
                if (additionalRemove != null)
                        additionalRemove.remove();
                disposed = true;
        }

        /**
         * Removes control point and attempts to reconnect next/prev
         * 
         * If this point is size change (PipeRuns are different on both sides), then reconnection cannot be made.
         */
        public void remove() {
                PipeControlPoint currentPrev = previous;
                PipeControlPoint currentNext = next;
                _remove();
                try {
                        if (currentNext != null)
                            if (!currentNext.checkRemove())
                                PipingRules.requestUpdate(currentNext);
                        if (currentPrev != null)
                            if (!currentPrev.checkRemove())
                                PipingRules.requestUpdate(currentPrev);
                } catch (Exception e) {
                        e.printStackTrace();
                }
        }
        
        
        /**
         * Removes control point without attempting to reconnect next/prev.
         * This usually leads to creation of another PipeRun for the control points after this point. 
         */
        public void removeAndSplit() {
        PipeControlPoint currentPrev = previous;
        PipeControlPoint currentNext = next;
        
        if (next != null && previous != null) {
            P3DRootNode root = (P3DRootNode)getPipelineComponent().getRootNode();
            PipeRun nextPipeRun = new PipeRun();
            nextPipeRun.setName(root.getUniqueName("PipeRun"));
            root.addChild(nextPipeRun);
            
            PipeRun previousRun = previous.getPipeRun();
            nextPipeRun.setPipeDiameter(previousRun.getPipeDiameter());
            nextPipeRun.setPipeThickness(previousRun.getPipeThickness());
            nextPipeRun.setTurnRadiusArray(previousRun.getTurnRadiusArray());
            
            PipelineComponent n = next.getPipelineComponent();
            while (n != null) {
                if (n.getPipeRun() != previousRun)
                    break;
                if (! (n instanceof Nozzle)) {
                    n.deattach();
                    nextPipeRun.addChild(n);
                } else
                    n.setPipeRun(nextPipeRun);
                n = n.getNext();
            }
        }
        _remove(false);
        try {
            if (currentNext != null)
                if (!currentNext.checkRemove())
                    PipingRules.requestUpdate(currentNext);
            if (currentPrev != null)
                if (!currentPrev.checkRemove())
                    PipingRules.requestUpdate(currentPrev);
        } catch (Exception e) {
            e.printStackTrace();
        }
    }
        
        /**
         * This is called when adjacent control point is removed.
         * 
         * This call should remove the give point, if the point cannot exist alone. 
         * At the moment there is one such case: branch.
         * 
         * @return
         */
        protected boolean checkRemove() {
            if (getParentPoint() != null) {
                return getParentPoint().checkRemove();
            } else {
                if (getPipelineComponent() == null)
                    return true; // already removed
            if (getPipelineComponent().getType().equals("Plant3D.URIs.Builtin_BranchSplitComponent")) {
                if (getChildPoints().get(0).getNext() == null && getChildPoints().get(0).getPrevious() == null) {
                        remove();
                        return true;
                }
            }
            return checkRemove(getPipeRun());
            }
    }

        private boolean checkRemove(PipeRun pipeRun) {
            if (pipeRun == null)
                return false;
                Collection<PipeControlPoint> points = pipeRun.getControlPoints();
                if (points.size() == 0) {
                        pipeRun.remove();
                        return true;
                } else if (points.size() == 1) {
                        PipeControlPoint pcp = points.iterator().next();
                        if (pcp.isDeletable() && pcp.getNext() == null && pcp.getPrevious() == null) {
                                pcp._remove(); // This call will recursively call also this method...
                                return true;
                        }
                } else if (points.size() == 2) {
                    
                }
                return false;
        }

        private void removeSubPoints() {
                for (PipeControlPoint p : children) {
                        p.parent = null;
                        p.component = null;
                        //p._remove();
                        PipeControlPoint currentNext = p.getNext();
                        PipeControlPoint currentPrev = p.getPrevious();
                        p._setNext(null);
                        p._setPrevious(null);
                        PipeRun run = p.getPipeRun();
                        if (run != null) {
                            run.remChild(p);
                            checkRemove(run);
                        }
                        if (currentNext != null)
                if (!currentNext.checkRemove())
                    PipingRules.requestUpdate(currentNext);
            if (currentPrev != null)
                if (!currentPrev.checkRemove())
                    PipingRules.requestUpdate(currentPrev);
            
                }
                children.clear();
        }

        private void removeParentPoint() {
                throw new RuntimeException("Child points cannot be removed directly");
        }
        
        public boolean isRemoved() {
            return component == null;
        }

        private void removeComponent() {
                if (component == null)
                        return;
                PipelineComponent next = component.getNext();
                PipelineComponent prev = component.getPrevious();
                PipelineComponent br0 = component.getBranch0();
                component.setNext(null);
                component.setPrevious(null);
                component.setBranch0(null);
                if (next != null) {
                        if (next.getNext() == component)
                                next.setNext(null);
                        else if (next.getPrevious() == component)
                                next.setPrevious(null);
                        else if (next.getBranch0() == component)
                                next.setBranch0(null);
                }
                if (prev != null) {
                        if (prev.getNext() == component)
                                prev.setNext(null);
                        else if (prev.getPrevious() == component)
                                prev.setPrevious(null);
                        else if (prev.getBranch0() == component)
                                prev.setBranch0(null);
                }
                if (br0 != null) {
                        if (br0.getNext() == component)
                                br0.setNext(null);
                        else if (br0.getPrevious() == component)
                                br0.setPrevious(null);
                        else if (br0.getBranch0() == component)
                                br0.setBranch0(null);
                }
                PipelineComponent comp = component;
                component = null;

                comp.remove();
        }

        @Override
        public void setOrientation(Quat4d orientation) {
                if (MathTools.equals(orientation, getOrientation()))
                        return;
                if (getPipelineComponent() != null && (getPipelineComponent() instanceof Nozzle))
                    System.out.println();
                super.setOrientation(orientation);
                if (getParentPoint() == null && component != null)
                        component._setWorldOrientation(getWorldOrientation());
                updateSubPoint();
        }

        @Override
        public void setPosition(Vector3d position) {
                if (MathTools.equals(position, getPosition()))
                        return;
                if (Double.isNaN(position.x) || Double.isNaN(position.y) || Double.isNaN(position.z))
                        throw new IllegalArgumentException("NaN is not supported");
                super.setPosition(position);
                if (getParentPoint() == null && component != null)
                        component._setWorldPosition(getWorldPosition());
                updateSubPoint();
        }
        
        private void updateSubPoint() {
                if (isOffset()) {
                        if (next == null && previous == null) {
                                for (PipeControlPoint sub : getChildPoints()) {
                                        sub.setWorldPosition(getWorldPosition());
                                        sub.setWorldOrientation(getWorldOrientation());
                                }
                                return;
                        }
                        for (PipeControlPoint sub : getChildPoints()) {
                                Vector3d wp = getWorldPosition();
                                wp.add(getSizeChangeOffsetVector());
                                sub.setWorldPosition(wp);
                                sub.setWorldOrientation(getWorldOrientation());
                        }
                } else {
                        for (PipeControlPoint sub : getChildPoints()) {
                                sub.setWorldPosition(getWorldPosition());
                                sub.setWorldOrientation(getWorldOrientation());
                        }
                }
        }


        public void _setWorldPosition(Vector3d position) {
                Vector3d localPos = getLocalPosition(position);
                super.setPosition(localPos);
                updateSubPoint();
        }

        public void _setWorldOrientation(Quat4d orientation) {
                Quat4d localOr = getLocalOrientation(orientation);
                super.setOrientation(localOr);
                updateSubPoint();
        }

        public void orientToDirection(Vector3d dir) {
                Double angleO = getRotationAngle();
                double angle = 0.0;
                if (angleO != null)
                        angle = angleO;
                boolean reversed = _getReversed();
                Quat4d q = null;
                if (dir != null) {
                    q = getControlPointOrientationQuat(dir, angle, reversed);
                } else {
                    q = getControlPointOrientationQuat(angle, reversed);
                }
                setWorldOrientation(q);
        }

        @Override
        public String toString() {
                return getClass().getName() + "@" + Integer.toHexString(hashCode());
        }

}