Example #1
0
        public static List <Vector2> FindPath(PathingMaster args)
        {
            var priority  = args.Priority;
            var startNode = args.Start;
            var endNode   = args.Target;

            if (startNode == endNode)
            {
                return(null);
            }

            if (!args.ValidateNodeForPath(endNode))
            {
                return(null);
            }

            startNode.G = 0;
            startNode.H = startNode.HDistance(endNode);
            startNode.F = startNode.H;

            priority.Add(startNode);
            for (var attempts = 0; !priority.Empty && attempts < 10; attempts++)
            {
                var jumpNode = priority.Top();
                if (jumpNode.Equals(endNode))
                {
                    return(ExpandPath(PathingNode.Backtrace(jumpNode)));
                }

                IdentifySuccessors(args, jumpNode);
            }
            return(null);
        }
Example #2
0
        private static void IdentifySuccessors(PathingMaster args, PathingNode activeNode)
        {
            activeNode.IsClosed = true;
            activeNode.IsOpen   = false;

            var priority = args.Priority;

            var neighbors = FindNeighbors(args, activeNode);

            foreach (var neighbor in neighbors)
            {
                int jX = 0, jY = 0;
                if (!Jump(args, neighbor.X, neighbor.Y, activeNode.X, activeNode.Y, ref jX, ref jY))
                {
                    continue;
                }

                var jumpNode = args.GetNode(jX, jY);
                if (jumpNode.IsClosed)
                {
                    continue;
                }

                var newG = activeNode.G + jumpNode.EuclideanDistance(activeNode);
                if ((jumpNode.IsOpen || jumpNode.IsClosed) && newG >= jumpNode.G)
                {
                    continue;
                }

                jumpNode.G      = newG;
                jumpNode.H      = jumpNode.HDistance(args.Target);
                jumpNode.F      = jumpNode.H + jumpNode.G;
                jumpNode.Parent = activeNode;

                if (jumpNode.IsOpen || jumpNode.IsClosed)
                {
                    priority.Update(jumpNode);
                }
                else
                {
                    priority.Add(jumpNode);
                }

                jumpNode.IsOpen   = true;
                jumpNode.IsClosed = false;
            }
        }
Example #3
0
        private static bool IdentifySuccessors(PathingMaster args, PathingNode activeNode)
        {
            var priority = args.Priority;
            var endNode  = args.Target;

            priority.Clear();
            activeNode.IsClosed = true;

            var any       = false;
            var neighbors = activeNode.GetNeighbors();

            foreach (var neighbor in neighbors)
            {
                var checkNode = args.GetNode(neighbor.X, neighbor.Y);
                if (checkNode == null)
                {
                    continue;
                }
                if (args.ValidateNodeForPath(checkNode))
                {
                    continue;
                }
                if (checkNode.IsClosed)
                {
                    continue;
                }

                //get angle, active to end
                var activeToEndAngle = activeNode.GetAngleRadian(endNode);
                //check arc
                if (activeNode.HasInArc(neighbor, activeToEndAngle, 2 * Math.PI / 3, 2.0f))
                {
                    //distance(h) + active to end angle difference from active to neighbor * 2(g) = f
                    var activeToNeighborAngle = activeNode.GetRelativeAngleRadian(neighbor, activeToEndAngle);
                    checkNode.G = Math.Abs(activeToEndAngle - activeToNeighborAngle) * 2;
                    checkNode.H = checkNode.HDistance(endNode);
                    checkNode.F = checkNode.G + checkNode.H;

                    //push to priority stack
                    priority.Add(checkNode);
                    any = true;
                }
            }

            return(any);
        }
Example #4
0
        public static IEnumerable <Vector2> FindPath(PathingMaster args)
        {
            var priority    = args.Priority;
            var endNode     = args.Target;
            var currentNode = args.Start;

            switch (true)
            {
            case true:
                while (IdentifySuccessors(args, currentNode))
                {
                    var newNode = priority.Top();

                    newNode.Parent = currentNode;
                    currentNode    = newNode;

                    yield return(new Vector2(currentNode.X, currentNode.Y));

                    if (currentNode.Equals(endNode))
                    {
                        yield break;
                    }
                }
                goto case false;

            case false:
                //count current path size
                var newCurrent = 0;
                var checkNode  = currentNode;
                for (; checkNode.Parent != null; newCurrent++)
                {
                    checkNode = currentNode.Parent;
                }

                //go back by half? (skips over closed nodes from last path)
                newCurrent /= 2;
                checkNode   = currentNode;
                for (var advanced = 0; advanced <= newCurrent && checkNode.Parent != null; advanced++)
                {
                    currentNode = checkNode.Parent;
                }

                //retry pathing
                goto case true;
            }
        }
Example #5
0
        private static IEnumerable <Position> FindNeighbors(PathingMaster args, PathingNode jumpNode)
        {
            var parent    = jumpNode.Parent;
            var x         = jumpNode.X;
            var y         = jumpNode.Y;
            var neighbors = new List <Position>();

            if (parent != null)
            {
                var px = parent.X;
                var py = parent.Y;

                var dx = (x - px) / Math.Max(Math.Abs(x - px), 1);
                var dy = (y - py) / Math.Max(Math.Abs(y - py), 1);

                if (dx != 0 && dy != 0)
                {
                    if (args.ValidateNodeForPath(x, y + dy))
                    {
                        neighbors.Add(new Position(x, y + dy));
                    }

                    if (args.ValidateNodeForPath(x + dx, y))
                    {
                        neighbors.Add(new Position(x + dx, y));
                    }

                    if (args.ValidateNodeForPath(x + dx, y + dy) && (args.ValidateNodeForPath(x, y + dy) || args.ValidateNodeForPath(x + dx, y)))
                    {
                        neighbors.Add(new Position(x + dx, y + dy));
                    }

                    if (args.ValidateNodeForPath(x - dx, y + dy) && args.ValidateNodeForPath(x, y + dy) && !args.ValidateNodeForPath(x - dx, y))
                    {
                        neighbors.Add(new Position(x - dx, y + dy));
                    }

                    if (!args.ValidateNodeForPath(x + dx, y - dy))
                    {
                        return(neighbors);
                    }

                    if (args.ValidateNodeForPath(x + dx, y) && !args.ValidateNodeForPath(x, y - dy))
                    {
                        neighbors.Add(new Position(x + dx, y - dy));
                    }
                }

                else if (dx == 0)
                {
                    if (!args.ValidateNodeForPath(x, y + dy))
                    {
                        return(neighbors);
                    }

                    neighbors.Add(new Position(x, y + dy));

                    if (args.ValidateNodeForPath(x + 1, y + dy) && !args.ValidateNodeForPath(x + 1, y))
                    {
                        neighbors.Add(new Position(x + 1, y + dy));
                    }

                    if (args.ValidateNodeForPath(x - 1, y + dy) && !args.ValidateNodeForPath(x - 1, y))
                    {
                        neighbors.Add(new Position(x - 1, y + dy));
                    }
                }
                else
                {
                    if (!args.ValidateNodeForPath(x + dx, y))
                    {
                        return(neighbors);
                    }

                    neighbors.Add(new Position(x + dx, y));

                    if (args.ValidateNodeForPath(x + dx, y + 1) && !args.ValidateNodeForPath(x, y + 1))
                    {
                        neighbors.Add(new Position(x + dx, y + 1));
                    }

                    if (args.ValidateNodeForPath(x + dx, y - 1) && !args.ValidateNodeForPath(x, y - 1))
                    {
                        neighbors.Add(new Position(x + dx, y - 1));
                    }
                }
            }

            else
            {
                neighbors.AddRange(from neighbor in jumpNode.GetNeighbors() where args.ValidateNodeForPath(neighbor) select new Position(neighbor.X, neighbor.Y));
            }

            return(neighbors);
        }
Example #6
0
        private static bool Jump(PathingMaster args, int x, int y, int pX, int pY, ref int jX, ref int jY)
        {
            if (!args.ValidateNodeForPath(x, y))
            {
                return(false);
            }

            if (args.Target.Equals(x, y))
            {
                jX = x;
                jY = y;
                return(true);
            }

            var dx = x - pX;
            var dy = y - pY;

            if (dx != 0 && dy != 0)
            {
                if (args.ValidateNodeForPath(x - dx, y + dy) && !args.ValidateNodeForPath(x - dx, y) || args.ValidateNodeForPath(x + dx, y - dy) && !args.ValidateNodeForPath(x, y - dy))
                {
                    jX = x;
                    jY = y;
                    return(true);
                }
            }
            else if (dx != 0)
            {
                if (args.ValidateNodeForPath(x + dx, y + 1) && !args.ValidateNodeForPath(x, y + 1) || args.ValidateNodeForPath(x + dx, y - 1) && !args.ValidateNodeForPath(x, y - 1))
                {
                    jX = x;
                    jY = y;
                    return(true);
                }
            }
            else if (args.ValidateNodeForPath(x + 1, y + dy) && !args.ValidateNodeForPath(x + 1, y) || args.ValidateNodeForPath(x - 1, y + dy) && !args.ValidateNodeForPath(x - 1, y))
            {
                jX = x;
                jY = y;
                return(true);
            }

            if (dx != 0 && dy != 0)
            {
                //jump x and y for diagonal neighbors
                var jx = Jump(args, x + dx, y, x, y, ref jX, ref jY);
                var jy = Jump(args, x, y + dy, x, y, ref jX, ref jY);
                if (jx || jy)
                {
                    jX = x;
                    jY = y;
                    return(true);
                }
            }

            if (args.ValidateNodeForPath(x + dx, y) || args.ValidateNodeForPath(x, y + dy))
            {
                return(Jump(args, x + dx, y + dy, x, y, ref jX, ref jY));
            }

            return(false);
        }