Exemplo n.º 1
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        /*****************************************
        Inspiration for finding the closest point :
        http://stackoverflow.com/questions/849211/shortest-distance-between-a-point-and-a-line-segment/1501725#1501725
        ******************************************/
        /// <summary>
        /// Find the closest point on a segment from another point. The segment is expected to be a straight line between two points
        /// </summary>
        /// <param name="lineStart">The first point of the segment</param>
        /// <param name="lineEnd">The last point of the segment</param>
        /// <param name="point">The point projected on the line</param>
        /// <param name="distance"></param>
        /// <returns></returns>
        public static Vertex GetClosestPointOnLine(Vertex lineStart, Vertex lineEnd, Vertex point, out double distance)
        {
            //Test if the line has a length <> 0
            double dist2 = ComputeSquareDistanceBetweenPoints(lineStart, lineEnd);
            if (dist2 == 0)
            {
                distance = ComputeDistanceBetweenPoints(point, lineStart);
                return lineStart;
            }

            //Compute the projection of on the line
            double t = ((point.X - lineStart.X) * (lineEnd.X - lineStart.X) + (point.Y - lineStart.Y) * (lineEnd.Y - lineStart.Y)) / dist2;

            if (t < 0)//point projection falls beyond the first node of the segment
            {
                distance = ComputeDistanceBetweenPoints(point, lineStart);
                return lineStart;
            }

            else if (t > 1)//point projection falls beyond the first node of the segment
            {
                distance = ComputeDistanceBetweenPoints(point, lineEnd);
                return lineEnd;
            }

            Vertex projectionPoint = new Vertex(lineStart.X + t * (lineEnd.X - lineStart.X), lineStart.Y + t * (lineEnd.Y - lineStart.Y));
            distance = ComputeDistanceBetweenPoints(point, projectionPoint);
            return projectionPoint;
        }
Exemplo n.º 2
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 /// <summary>
 /// Fetch the distance between two points
 /// </summary>
 /// <param name="p1">A point</param>
 /// <param name="p2">A point</param>
 /// <returns></returns>
 public static double ComputeDistanceBetweenPoints(Vertex p1, Vertex p2)
 {
     if (p1.X == p2.X && p1.Y == p2.Y)
     {
         return 0;
     }
     return Math.Sqrt(ComputeSquareDistanceBetweenPoints(p1, p2));
 }
 public ParabolaProblemInformation(Vertex focusPoint, Vertex directixSegmentStart, Vertex directixSegmentEnd, Vertex parabolaStart, Vertex parabolaEnd)
 {
     FocusPoint = focusPoint;
     DirectixSegmentStart = directixSegmentStart;
     DirectixSegmentEnd = directixSegmentEnd;
     ParabolaStart = parabolaStart;
     ParabolaEnd = parabolaEnd;
 }
Exemplo n.º 4
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        /// <summary>
        /// Undo the rotation done for a point.
        /// </summary>
        /// <param name="p">The point to rotate.</param>
        /// <param name="theta">The angle in radians</param>
        /// <param name="shift_x">The translation along the x-axis used during the rotation.</param>
        /// <param name="shift_y">The translation along the y-axis used during the rotation.</param>
        /// <returns></returns>
        public static Vertex Unrotate(Vertex p, double theta, double shift_x, double shift_y)
        {
            double cos = Math.Cos(theta);
            double sin = Math.Sin(theta);

            return new Vertex(
                (p.X * cos) - (p.Y * sin) + shift_x,
                (p.X * sin) + (p.Y * cos) + shift_y
                );
        }
Exemplo n.º 5
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 /// <summary>
 /// Rotate a point around another point (anchor)
 /// </summary>
 /// <param name="point">The anchor point used for the rotation</param>
 /// <param name="theta">The angle for the rotation</param>
 /// <returns>The rotated point</returns>
 public static Vertex Rotate(Vertex point, double theta)
 {
     double t = -1 * theta;
     double cos = Math.Cos(t);
     double sin = Math.Sin(t);
     return new Vertex(
         (point.X * cos) - (point.Y * sin),
         (point.X * sin) + (point.Y * cos)
         );
 }
        public UnsolvableVertexException(ParabolaProblemInformation nonRotatedInformation, ParabolaProblemInformation rotatedInformation, Vertex boostVertex, Vertex computedVertex,
            double distanceBoostVertexToFocus, double distanceComputedVertexToFocus, double distanceBoostVertexToDirectix, double distanceComputedVertexToDirectix)
        {
            InputParabolaProblemInfo = nonRotatedInformation;
            RoatatedParabolaProblemInfo = rotatedInformation;

            BoostVertex = boostVertex;
            ComputedVertex = computedVertex;

            DistanceBoostVertexToFocus = distanceBoostVertexToFocus;
            DistanceComputedVertexToFocus = distanceComputedVertexToFocus;
            DistanceBoostVertexToDirectix = distanceBoostVertexToDirectix;
            DistanceComputedVertexToDirectix = distanceComputedVertexToDirectix;
        }
Exemplo n.º 7
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 /// <summary>
 /// Compute the vector between two points
 /// </summary>
 /// <param name="lineStart">The first point of the segment</param>
 /// <param name="lineEnd">The last point of the segment</param>
 /// <returns></returns>
 public static Vertex ComputeVector(Vertex lineStart, Vertex lineEnd)
 {
     return new Vertex(lineEnd.X - lineStart.X, lineEnd.Y - lineStart.Y);
 }
Exemplo n.º 8
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 /// <summary>
 /// Fetch the square distance between 2 points
 /// </summary>
 /// <param name="p1">A point</param>
 /// <param name="p2">A point</param>
 /// <returns></returns>
 public static double ComputeSquareDistanceBetweenPoints(Vertex p1, Vertex p2)
 {
     return Math.Pow(p1.X - p2.X, 2) + Math.Pow(p1.Y - p2.Y, 2);
 }
Exemplo n.º 9
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        /// <summary>
        /// Compute a point on the line at a specific distance.
        /// </summary>
        /// <param name="p1">The first point of the line.</param>
        /// <param name="p2">The last point of the line.</param>
        /// <param name="distanceOnLine">The distance on the line where the point will be fetched.</param>
        /// <returns></returns>
        public static Vertex GetPointAtDistance(Vertex p1, Vertex p2, double distanceOnLine)
        {
            double dx = p2.X - p1.X;
            double dy = p2.Y - p1.Y;
            double l = Math.Sqrt(Math.Pow(dx,2) + Math.Pow(dy,2));
            if(distanceOnLine > l)
                throw new Exception ("Length is greater than the length of the segment");

            return new Vertex(p1.X + dx/l * distanceOnLine, p1.Y + dy/l * distanceOnLine);
        }
Exemplo n.º 10
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 /// <summary>
 /// Find the closest point on a segment from another point. The segment is expected to be a straight line between two points
 /// </summary>
 /// <param name="lineStart">The first point of the segment</param>
 /// <param name="lineEnd">The last point of the segment</param>
 /// <param name="point">The point projected on the line</param>
 /// <returns></returns>
 public static Vertex GetClosestPointOnLine(Vertex lineStart, Vertex lineEnd, Vertex point)
 {
     double distance = 0;
     return GetClosestPointOnLine(lineStart, lineEnd, point, out distance);
 }
Exemplo n.º 11
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 /// <summary>
 /// Rotate a point by an angle around another point (origin). 
 /// The rotation happen clockwise. 
 /// https://www.siggraph.org/education/materials/HyperGraph/modeling/mod_tran/2drota.htm
 /// The orgin point is computed as the point moved by a shift on X and Y axis.
 /// </summary>
 /// <param name="p">The point to be rotated</param>
 /// <param name="theta">The angle for the rotation (in radians).</param>
 /// <param name="shift_x">The translation along the x-axis used during the rotation.</param>
 /// <param name="shift_y">The translation along the y-axis used during the rotation.</param>
 /// <returns></returns>
 public static Vertex Rotate(Vertex p, double theta, double shift_x, double shift_y)
 {
     return Rotate(new Vertex(p.X - shift_x, p.Y - shift_y), theta);
 }
Exemplo n.º 12
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        /// <summary>
        /// Interpolate parabola points between two points. The equation is computed by turning the input segment
        /// into the directix of the parabola, and the input point into the focus of the parabola. The directix used
        /// to solve the parabola is horizontal (parallel to x-axis).
        /// </summary>
        /// <param name="focus">The input point that will be used as a focus point.</param>
        /// <param name="dir">The input segment that will be used a the directix</param>
        /// <param name="par_start">The point on the parabola used as a starting point.</param>
        /// <param name="par_end">The point on the parabola used as a ending point.</param>
        /// <param name="max_distance">The maximum distance between 2 points on the parabola</param>
        /// <param name="tolerance">The maximum distance between 2 points on the parabola</param>
        /// <returns></returns>
        public static List<Vertex> Densify(Vertex focus, Vertex dir_start, Vertex dir_end, Vertex par_start, Vertex par_end, double max_distance, double tolerance)
        {
            if (max_distance <= 0)
                throw new ArgumentOutOfRangeException(String.Format("The maximum distance must be greater than 0. Value passed: {0}", max_distance));

            if (tolerance < 0)
                throw new ArgumentOutOfRangeException(String.Format("The tolerance must be greater than or equal to 0. Value passed: {0}", tolerance));

            #region Rotate Input Points

            //Compute the information required to perform rotation
            double shift_X = Math.Min(dir_start.X, dir_end.X);
            double shift_Y = Math.Min(dir_start.Y, dir_end.Y);
            double angle = GetLineAngleAsRadiant(dir_start, dir_end);

            Vertex focus_rotated = Rotation.Rotate(
                focus,
                angle,
                shift_X,
                shift_Y
            );

            Vertex dir_startPoint_rotated = Rotation.Rotate(
                dir_start,
                angle,
                shift_X,
                shift_Y
            );

            Vertex dir_endPoint_rotated = Rotation.Rotate(
                dir_end,
                angle,
                shift_X,
                shift_Y);

            Vertex par_startPoint_rotated = Rotation.Rotate(
                par_start,
                angle,
                shift_X,
                shift_Y
            );

            Vertex par_endPoint_rotated = Rotation.Rotate(
                par_end,
                angle,
                shift_X,
                shift_Y
            );

            #endregion

            #region Validate the equation on first and last points given by Boost
            //Set parabola parameters
            double directrix = dir_endPoint_rotated.Y;
            double snapTolerance = 5;

            List<Vertex> densified_rotated = new List<Vertex>();
            Stack<Vertex> next = new Stack<Vertex>();

            ParabolaProblemInformation nonRotatedInformation = new ParabolaProblemInformation(
                    focus,
                    dir_start,
                    dir_end,
                    par_start,
                    par_end
            );

            double distanceFocusToDirectix = 0;
            Distance.GetClosestPointOnLine(focus, dir_start, dir_end, out distanceFocusToDirectix);
            if (distanceFocusToDirectix == 0)
                throw new FocusOnDirectixException(nonRotatedInformation);

            ParabolaProblemInformation rotatedInformation = new ParabolaProblemInformation(
                focus_rotated,
                dir_startPoint_rotated,
                dir_endPoint_rotated,
                par_startPoint_rotated,
                par_endPoint_rotated
            );

            List<Tuple<Vertex, Vertex>> points = new List <Tuple<Vertex, Vertex>>();
            points.Add(
                Tuple.Create<Vertex, Vertex>(
                    par_startPoint_rotated,
                    new Vertex(par_startPoint_rotated.X, ParabolaY(par_startPoint_rotated.X, focus_rotated, directrix))
                 )
            );

            points.Add(
                Tuple.Create<Vertex, Vertex>(
                    par_endPoint_rotated,
                    new Vertex(par_endPoint_rotated.X, ParabolaY(par_endPoint_rotated.X, focus_rotated, directrix))
                 )
            );

            foreach (var point in points)
            {
                double delta = point.Item1.Y > point.Item2.Y ?
                        point.Item1.Y - point.Item2.Y : point.Item2.Y - point.Item1.Y;

                if (delta > snapTolerance)
                {
                    GenerateParabolaIssueInformation(rotatedInformation, nonRotatedInformation, point.Item1, point.Item2, 0.001);
                    throw new Exception(
                        String.Format(
                            "The computed Y on the parabola for the starting / ending point is different from the rotated point returned by Boost. Difference: {0}",
                            delta)
                         );
                }
            }
            #endregion

            #region Compute Intermediate Points (Rotated)
            Vertex previous = points[0].Item2;
            densified_rotated.Add(previous);
            next.Push(points[1].Item2);

            while (next.Count > 0)
            {
                Vertex current = next.Peek();
                double mid_cord_x = (previous.X + current.X) / 2;
                Vertex mid_curve = new Vertex(mid_cord_x, ParabolaY(mid_cord_x, focus_rotated, directrix));
                double distance = Distance.ComputeDistanceBetweenPoints(current, previous);
                if (distance > max_distance)
                {
                    next.Push(mid_curve);
                }
                else
                {
                    next.Pop();
                    densified_rotated.Add(current);
                    previous = current;
                }
            }
            #endregion

            #region Unrotate and validate
            List<Vertex> densified = densified_rotated.Select(w => Rotation.Unrotate(w, angle, shift_X, shift_Y)).ToList();

            //reset the first and last points so they match exactly.
            if (Math.Abs(densified[0].X - par_start.X) > snapTolerance ||
                Math.Abs(densified[0].Y - par_start.Y) > snapTolerance)
                throw new Exception(String.Format("Segmented curve start point is not correct. Tolerance exeeded in X ({0}) or Y ({1})",
                    Math.Abs(densified[0].X - par_start.X), Math.Abs(densified[0].Y - par_start.Y)));
            densified[0] = par_start;

            if (Math.Abs(densified[densified.Count - 1].X - par_end.X) > snapTolerance ||
                Math.Abs(densified[densified.Count - 1].Y - par_end.Y) > snapTolerance)
                throw new Exception(String.Format("Segmented curve end point is not correct. Tolerance exeeded in X ({0}) or Y ({1})",
                    Math.Abs(densified[densified.Count - 1].X - par_end.X), Math.Abs(densified[densified.Count - 1].Y - par_end.Y)));
            densified[densified.Count - 1] = par_end;
            #endregion

            return densified;
        }
Exemplo n.º 13
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 /// <summary>
 /// Find the position of y on the parabolar given focus and directix y. The equation to find a point on the parabola
 /// given those two value is: (x−a)2+b2−c2=2(b−c)y so y=((x−a)2+b2−c2)/2(b−c)
 /// </summary>
 /// <param name="x">The x value for which a y value is wanted</param>
 /// <param name="focus">The focus of the parabola</param>
 /// <param name="directrix_y">The y value of the directx line</param>
 /// <returns>The y value associated with x</returns>
 static double ParabolaY(double x, Vertex focus, double directrix_y)
 {
     return (Math.Pow(x - focus.X, 2) + Math.Pow(focus.Y, 2) - Math.Pow(directrix_y, 2)) / (2 * (focus.Y - directrix_y));
 }
Exemplo n.º 14
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 /// <summary>
 /// Return the angle between 2 points as radians
 /// </summary>
 /// <param name="start">The first point</param>
 /// <param name="end">The second point</param>
 /// <returns>The angle in radians</returns>
 static double GetLineAngleAsRadiant(Vertex start, Vertex end)
 {
     return Math.Atan2(end.Y - start.Y, end.X - start.X);
 }
Exemplo n.º 15
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        /// <summary>
        /// Generate an exception when the point computed by the parabola equation is different from the point computed by boost.
        /// </summary>
        /// <param name="rotatedInformation">The information used to solve parabola. This is the is the information before the rotation.</param>
        /// <param name="nonRotatedInformation">The information used to solve parabola. This is the is the information after the rotation.</param>
        /// <param name="boostPoint">The point on the parabola returned by Boost.</param>
        /// <param name="parabolaPoint">The point on the parabola computed.</param>
        /// <param name="tolerance">The tolerance used to decide if an exception need to be raise.</param>
        private static void GenerateParabolaIssueInformation(ParabolaProblemInformation rotatedInformation, ParabolaProblemInformation nonRotatedInformation, Vertex boostPoint, Vertex parabolaPoint, double tolerance)
        {
            if (tolerance < 0)
                throw new ArgumentOutOfRangeException(String.Format("Tolenrance must be greater than 0"));

            double minX = Math.Min(Math.Min(Math.Min(rotatedInformation.DirectixSegmentStart.X, rotatedInformation.DirectixSegmentStart.X), boostPoint.X), parabolaPoint.X);
            double maxX = Math.Max(Math.Max(Math.Max(rotatedInformation.DirectixSegmentStart.X, rotatedInformation.DirectixSegmentStart.X), boostPoint.X), parabolaPoint.X);

            //Compute the distance between the input parabola point
            double distanceBoostPointToFocus = Distance.ComputeDistanceBetweenPoints(boostPoint, rotatedInformation.FocusPoint);
            double distanceBoostPointToDirectix = 0;
            Distance.GetClosestPointOnLine(
                    new Vertex(minX, rotatedInformation.DirectixSegmentEnd.Y),
                    new Vertex(maxX, rotatedInformation.DirectixSegmentEnd.Y),
                    boostPoint,
                    out distanceBoostPointToDirectix
            );

            double distanceComputedPointToFocus = Distance.ComputeDistanceBetweenPoints(parabolaPoint, rotatedInformation.FocusPoint);
            double distanceComputedPointToDirectix = 0;
            Distance.GetClosestPointOnLine(
                    new Vertex(minX, rotatedInformation.DirectixSegmentEnd.Y),
                    new Vertex(maxX, rotatedInformation.DirectixSegmentEnd.Y),
                    parabolaPoint,
                    out distanceComputedPointToDirectix
            );

            double distanceDiff = distanceComputedPointToFocus > distanceComputedPointToDirectix ?
                distanceComputedPointToFocus - distanceComputedPointToDirectix : distanceComputedPointToDirectix - distanceComputedPointToFocus;

            if (distanceDiff < tolerance || Double.IsNaN(distanceDiff) || Double.IsInfinity(distanceDiff))
                throw new UnsolvableVertexException(nonRotatedInformation, rotatedInformation, boostPoint, parabolaPoint,
                    distanceBoostPointToFocus, distanceComputedPointToFocus, distanceBoostPointToDirectix, distanceComputedPointToDirectix);
        }