if (!PipingRules.enabled)
return false;
- if (requestUpdates.size() == 0)
- return false;
-
- List<PipeControlPoint> temp = new ArrayList<PipeControlPoint>(requestUpdates.size());
- synchronized(updateMutex) {
+ List<PipeControlPoint> temp;
+ synchronized(updateMutex) {
+ if (requestUpdates.size() == 0)
+ return false;
+
+ temp = new ArrayList<PipeControlPoint>(requestUpdates.size());
temp.addAll(requestUpdates);
requestUpdates.clear();
}
scp.setWorldPosition(pos);
Vector3d dir = new Vector3d();
dir.sub(pcp2.getWorldPosition(), pcp1.getWorldPosition());
- updateControlPointOrientation(scp, dir);
+ scp.orientToDirection(dir);
scp.setLength(length);
validate(scp.getPipeRun());
return scp;
}
+ /**
+ * Calculate offset based on a given fixed component direction.
+ *
+ * The desired component direction is provided as an input to this method,
+ * unlike the direction vector that is calculated by calculateOffset.
+ *
+ * The returned offset vector is always perpendicular to the given direction
+ * vector.
+ *
+ * @param startPoint Start point of leg
+ * @param endPoint End point of leg
+ * @param start Starting component of leg
+ * @param list Inline components between start and end
+ * @param end Ending component of leg
+ * @param dir Direction at which the offset is calculated
+ * @param offset A vector object to receive the offset vector values
+ * @return True if offsets are present
+ */
public static boolean calculateDirectedOffset(Vector3d startPoint, Vector3d endPoint, PipeControlPoint start, ArrayList<PipeControlPoint> list, PipeControlPoint end, Vector3d dir, Vector3d offset) {
return calculateOffset(startPoint, endPoint, start, list, end, dir, offset, true);
}
+ /**
+ * Calculate offset and direction vectors for a path leg so that the given chain
+ * of components starts and ends at the given coordinates
+ *
+ * The returned direction and offset vectors are perpendicular to each other.
+ *
+ * @param startPoint Start point of the leg
+ * @param endPoint End point of the leg
+ * @param start Starting component of the leg
+ * @param list Inline components between start and end
+ * @param end Ending component of the leg
+ * @param dir A vector object to receive the component direction vector
+ * @param offset A vector object to receive the offset vector
+ * @return True if offsets are present
+ */
public static boolean calculateOffset(Vector3d startPoint, Vector3d endPoint, PipeControlPoint start, ArrayList<PipeControlPoint> list, PipeControlPoint end, Vector3d dir, Vector3d offset) {
return calculateOffset(startPoint, endPoint, start, list, end, dir, offset, false);
}
} else {
Vector3d sp = new Vector3d(startPoint);
Point3d ep = new Point3d(endPoint);
- dir.set(ep);
- dir.sub(sp);
+ if (!directed) {
+ dir.set(ep);
+ dir.sub(sp);
+ }
+
double l = dir.lengthSquared();
if (l > MathTools.NEAR_ZERO)
dir.scale(1.0/Math.sqrt(l));
continue;
double curr = gapObj.d;
int d = 1;
- while (curr < -MIN_INLINE_LENGTH) {
- GapObj next = i+d >= 0 ? gaps.get(i+d) : null;
+ while (d < gaps.size() && curr < -MIN_INLINE_LENGTH) {
+ GapObj next = i+d < gaps.size() ? gaps.get(i+d) : null;
GapObj prev = i-d >= 0 ? gaps.get(i-d) : null;
if (next != null && next.gap == Gap.SPACE) {
double move = Math.min(-curr, next.d);
pcp.first.setWorldPosition(p);
}
}
- if (curr < -MIN_INLINE_LENGTH && prev != null && prev.gap == Gap.SPACE) {
+ else if (prev != null && prev.gap == Gap.SPACE) {
double move = Math.min(-curr, prev.d);
curr+= move;
- next.d -= move;
- if (next.d < MIN_INLINE_LENGTH)
- next.gap = Gap.ATTACHED;
+ prev.d -= move;
+ if (prev.d < MIN_INLINE_LENGTH)
+ prev.gap = Gap.ATTACHED;
Vector3d mv = new Vector3d(dir);
mv.normalize();
mv.scale(-move);
pcp.first.setWorldPosition(p);
}
}
+ else {
+ d++;
+ }
}
}
} else {
Point3d otherPosition = new Point3d(dcpStart ? u.endPoint : u.startPoint);
if (u.hasOffsets) {
- Vector3d dir = new Vector3d(), offset = new Vector3d();
+ Vector3d dir = dcp.getDirection(dcpStart ? Direction.NEXT : Direction.PREVIOUS);
+ if (!dcpStart)
+ dir.negate();
+
+ Vector3d offset = new Vector3d();
calculateDirectedOffset(u.startPoint, u.endPoint, u.start, u.list, u.end, dir, offset);
u.dir = dir;
u.offset = offset;
if (dcpStart)
- otherPosition.add(offset);
- else
otherPosition.sub(offset);
+ else
+ otherPosition.add(offset);
}
double mu[] = new double[2];
Point3d position1 = new Point3d(u.startPoint);
Point3d position2 = new Point3d(u.endPoint);
- Vector3d dir = new Vector3d(), offset = new Vector3d();
+ Vector3d dir = u.start.getDirection(Direction.NEXT), offset = new Vector3d();
calculateDirectedOffset(new Vector3d(position1), new Vector3d(position2), u.start, u.list, u.end, dir, offset);
Point3d position1offset = new Point3d(position1);
else if (d < -0.9999)
return tr*2.0; // point following turn is directly behind the nozzle, in theory, we should return Double.Inf...
- double curr = tr*0.1;
+ double curr = 0.0;
int iter = 10;
Vector3d tp0 = tcp.getPosition();
try {
while (iter > 0) {
Vector3d tp = new Vector3d(dir);
tp.scaleAdd(curr, dp);
- tcp.setPosition(tp);
+ tcp._setPosition(tp); // no firing of listeners here
if (other == ne) {
dir2 = pathLegDirection(tcp);
} else {
}
double a = dir.angle(dir2);
- double t = Math.tan(a * 0.5);
- double R = 0.0;
- if (t > MathTools.NEAR_ZERO)
- R = tr * t;
+
+ // other is directly between dcp and tcp, a zero angle turn should do
+ if (Math.PI - a <= MathTools.NEAR_ZERO)
+ return 0.0;
+
+ double R = tr * Math.tan(a * 0.5);
if (R <= curr)
break;
curr = R*1.001;
}
}
finally {
- tcp.setPosition(tp0);
+ tcp._setPosition(tp0); // return the original value
}
return curr;
}
} else if (u.start.isEnd()) {
updateEndComponentControlPoint(u.start, u.dir);
} else if (u.start.isInline()) {
- updateControlPointOrientation(u.start, u.dir);
+ u.start.orientToDirection(u.dir);
}
if (u.end.isTurn()) {
//updateTurnControlPointTurn(u.end, u.end.getPrevious(), u.end.getNext());
} else if (u.end.isEnd()) {
updateEndComponentControlPoint(u.end, u.dir);
} else if (u.end.isInline()) {
- updateControlPointOrientation(u.end, u.dir);
+ u.end.orientToDirection(u.dir);
}
} else {
System.out.println(" " + newInlinePoint);
icp.setWorldPosition(newInlinePoint);
- updateControlPointOrientation(icp, dir);
+ icp.orientToDirection(dir);
}
/**
System.out.println("PipingRules.updateEndComponentControlPoint() " + ecp);
if (!ecp.isFixed()) // prevent overriding nozzle orientations..
- updateControlPointOrientation(ecp, dir);
+ ecp.orientToDirection(dir);
for (PipeControlPoint pcp : ecp.getChildPoints()) {
// TODO update position
}
}
- private static void updateControlPointOrientation(PipeControlPoint pcp, Vector3d dir) {
- Double angleO = pcp.getRotationAngle();
- double angle = 0.0;
- if (angleO != null)
- angle = angleO;
- boolean reversed = pcp._getReversed();
- Quat4d q = null;
- if (dir != null) {
- q = pcp.getControlPointOrientationQuat(dir, angle, reversed);
- } else {
- q = pcp.getControlPointOrientationQuat(angle, reversed);
- }
- pcp.setWorldOrientation(q);
- }
-
/**
* Updates all branches when branch's position has been changed
*
return tcp.getTurnAngle();
return Math.PI; // FIXME : argh
}
- double turnAngle = prev.angle(next);
+
+ final boolean isDegenerate = prev.lengthSquared() < MathTools.NEAR_ZERO || next.lengthSquared() < MathTools.NEAR_ZERO;
+ double turnAngle = isDegenerate ? 0.0 : prev.angle(next);
Vector3d turnAxis = new Vector3d();
turnAxis.cross(prev, next);
tcp.setTurnAxis(new Vector3d(MathTools.Y_AXIS));
}
- updateControlPointOrientation(tcp,prev);
+ tcp.orientToDirection(prev);
if (DEBUG)
System.out.println("PipingTools.updateTurnControlPointTurn " + prev + " " + next + " " + turnAngle + " " + turnAxis);
public static void validate(PipeRun pipeRun) {
if (pipeRun == null)
return;
- Collection<PipeControlPoint> pcps = pipeRun.getControlPoints();
- int count = 0;
- //System.out.println("Validate " + pipeRun.getName());
- for (PipeControlPoint pcp : pcps) {
- if (pcp.getParentPoint() == null || pcp.getParentPoint().getPipeRun() != pipeRun)
- count++;
- }
- List<PipeControlPoint> runPcps = getControlPoints(pipeRun);
- if (runPcps.size() != count) {
- System.out.println("Run " + pipeRun.getName() + " contains unconnected control points, found " + runPcps.size() + " connected, " + pcps.size() + " total.");
+ synchronized (ruleMutex) {
+ Collection<PipeControlPoint> pcps = pipeRun.getControlPoints();
+ int count = 0;
+ //System.out.println("Validate " + pipeRun.getName());
for (PipeControlPoint pcp : pcps) {
- if (!runPcps.contains(pcp)) {
- System.out.println("Unconnected " + pcp + " " + pcp.getPipelineComponent());
- }
+ if (pcp.getParentPoint() == null || pcp.getParentPoint().getPipeRun() != pipeRun)
+ count++;
}
- }
- for (PipeControlPoint pcp : pcps) {
- if (pcp.getPipeRun() == null) {
- System.out.println("PipeRun ref missing " + pcp + " " + pcp.getPipelineComponent());
- }
- if (!pcp.isDirected() && pcp.getNext() == null && pcp.getPrevious() == null)
- System.out.println("Orphan undirected " + pcp + " " + pcp.getPipelineComponent());
- }
- for (PipeControlPoint pcp : pcps) {
- if (pcp.getParentPoint() == null) {
- PipeControlPoint sub = null;
- if (pcp.isDualInline())
- sub = pcp.getDualSub();
- PipeControlPoint next = pcp.getNext();
- PipeControlPoint prev = pcp.getPrevious();
- if (next != null) {
- if (!(next.getPrevious() == pcp || next.getPrevious() == sub)) {
- System.out.println("Inconsistency between " + pcp + " -> " +next );
- }
+ List<PipeControlPoint> runPcps = getControlPoints(pipeRun);
+ if (runPcps.size() != count) {
+ System.out.println("Run " + pipeRun.getName() + " contains unconnected control points, found " + runPcps.size() + " connected, " + pcps.size() + " total.");
+ for (PipeControlPoint pcp : pcps) {
+ if (!runPcps.contains(pcp)) {
+ System.out.println("Unconnected " + pcp + " " + pcp.getPipelineComponent());
+ }
}
- if (prev != null) {
- PipeControlPoint prevParent = null;
- if (prev.isDualSub()) {
- prevParent = prev.getParentPoint();
- } else if (prev.isDualInline()) {
- System.out.println("Inconsistency between " + pcp + " <-- " +prev );
+ }
+ for (PipeControlPoint pcp : pcps) {
+ if (pcp.getPipeRun() == null) {
+ System.out.println("PipeRun ref missing " + pcp + " " + pcp.getPipelineComponent());
+ }
+ if (!pcp.isDirected() && pcp.getNext() == null && pcp.getPrevious() == null)
+ System.out.println("Orphan undirected " + pcp + " " + pcp.getPipelineComponent());
+ }
+ for (PipeControlPoint pcp : pcps) {
+ if (pcp.getParentPoint() == null) {
+ PipeControlPoint sub = null;
+ if (pcp.isDualInline())
+ sub = pcp.getDualSub();
+ PipeControlPoint next = pcp.getNext();
+ PipeControlPoint prev = pcp.getPrevious();
+ if (next != null) {
+ if (!(next.getPrevious() == pcp || next.getPrevious() == sub)) {
+ System.out.println("Inconsistency between " + pcp + " -> " +next );
+ }
}
- if (!(prev.getNext() == pcp && (prevParent == null || prevParent.getNext() == pcp))) {
- System.out.println("Inconsistency between " + pcp + " <-- " +prev );
+ if (prev != null) {
+ PipeControlPoint prevParent = null;
+ if (prev.isDualSub()) {
+ prevParent = prev.getParentPoint();
+ } else if (prev.isDualInline()) {
+ System.out.println("Inconsistency between " + pcp + " <-- " +prev );
+ }
+ if (!(prev.getNext() == pcp && (prevParent == null || prevParent.getNext() == pcp))) {
+ System.out.println("Inconsistency between " + pcp + " <-- " +prev );
+ }
}
}
}