public override void Process(object param) { if (!base.BeginProcess()) { return; } if (param is ZoneTravelingBehavior) { HandleBaseBehavior((ZoneTravelingBehavior)param); } extraObstacles = GetPerimeterObstacles(); if (reverseGear) { ProcessReverse(); return; } AbsoluteTransformer absTransform = Services.StateProvider.GetAbsoluteTransformer(curTimestamp); // get the vehicle relative path LinePath relRecommendedPath = recommendedPath.Transform(absTransform); LinePath.PointOnPath zeroPoint = relRecommendedPath.ZeroPoint; // get the distance to the end point double distToEnd = relRecommendedPath.DistanceBetween(zeroPoint, relRecommendedPath.EndPoint); // get the planning distance double planningDist = GetPlanningDistance(); planningDist = Math.Max(planningDist, 20); planningDist -= zeroPoint.Location.Length; if (planningDist < 2.5) { planningDist = 2.5; } if (distToEnd < planningDist) { // make the speed command at stop speed command behaviorTimestamp = curTimestamp; speedCommand = new StopAtDistSpeedCommand(distToEnd - TahoeParams.FL); planningDist = distToEnd; approachSpeed = recommendedSpeed.Speed; settings.endingHeading = relRecommendedPath.EndSegment.UnitVector.ArcTan; settings.endingPositionFixed = true; settings.endingPositionMax = 2; settings.endingPositionMin = -2; } else { speedCommand = new ScalarSpeedCommand(recommendedSpeed.Speed); } // get the distance of the path segment we care about LinePath pathSegment = relRecommendedPath.SubPath(zeroPoint, planningDist); double avoidanceDist = planningDist + 5; avoidanceBasePath = relRecommendedPath.SubPath(zeroPoint, ref avoidanceDist); if (avoidanceDist > 0) { avoidanceBasePath.Add(avoidanceBasePath.EndPoint.Location + avoidanceBasePath.EndSegment.Vector.Normalize(avoidanceDist)); } // test if we should clear out of arc mode if (arcMode) { if (TestNormalModeClear(relRecommendedPath, zeroPoint)) { prevCurvature = double.NaN; arcMode = false; } } if (Math.Abs(zeroPoint.AlongtrackDistance(Coordinates.Zero)) > 1) { pathSegment.Insert(0, Coordinates.Zero); } else { if (pathSegment[0].DistanceTo(pathSegment[1]) < 1) { pathSegment.RemoveAt(0); } pathSegment[0] = Coordinates.Zero; } if (arcMode) { Coordinates relativeGoalPoint = relRecommendedPath.EndPoint.Location; ArcVoteZone(relativeGoalPoint, extraObstacles); return; } double pathLength = pathSegment.PathLength; if (pathLength < 6) { double additionalDist = 6.25 - pathLength; pathSegment.Add(pathSegment.EndPoint.Location + pathSegment.EndSegment.Vector.Normalize(additionalDist)); } // determine if polygons are to the left or right of the path for (int i = 0; i < zoneBadRegions.Length; i++) { Polygon poly = zoneBadRegions[i].Transform(absTransform); int numLeft = 0; int numRight = 0; foreach (LineSegment ls in pathSegment.GetSegmentEnumerator()) { for (int j = 0; j < poly.Count; j++) { if (ls.IsToLeft(poly[j])) { numLeft++; } else { numRight++; } } } if (numLeft > numRight) { // we'll consider this polygon on the left of the path //additionalLeftBounds.Add(new Boundary(poly, 0.1, 0.1, 0)); } else { //additionalRightBounds.Add(new Boundary(poly, 0.1, 0.1, 0)); } } // TODO: add zone perimeter disablePathAngleCheck = false; laneWidthAtPathEnd = 7; settings.Options.w_diff = 3; smootherBasePath = new LinePath(); smootherBasePath.Add(Coordinates.Zero); smootherBasePath.Add(pathSegment.EndPoint.Location); AddTargetPath(pathSegment, 0.005); settings.maxSpeed = recommendedSpeed.Speed; useAvoidancePath = false; SmoothAndTrack(command_label, true); }