I'm having trouble effectively implementing this generic method featured by Eric Lippert. His blog outlines a very simple and effective means of creating an A Star algorithm (found here). Here's the quick run down.

The code for the actual path finding:

```
class Path<Node> : IEnumerable<Node>
{
public Node LastStep { get; private set; }
public Path<Node> PreviousSteps { get; private set; }
public double TotalCost { get; private set; }
private Path(Node lastStep, Path<Node> previousSteps, double totalCost)
{
LastStep = lastStep;
PreviousSteps = previousSteps;
TotalCost = totalCost;
}
public Path(Node start) : this(start, null, 0) { }
public Path<Node> AddStep(Node step, double stepCost)
{
return new Path<Node>(step, this, TotalCost + stepCost);
}
public IEnumerator<Node> GetEnumerator()
{
for (Path<Node> p = this; p != null; p = p.PreviousSteps)
yield return p.LastStep;
}
IEnumerator IEnumerable.GetEnumerator()
{
return this.GetEnumerator();
}
}
class AStar
{
static public Path<Node> FindPath<Node>(
Node start,
Node destination,
Func<Node, Node, double> distance,
Func<Node, double> estimate)
where Node : IHasNeighbours<Node>
{
var closed = new HashSet<Node>();
var queue = new PriorityQueue<double, Path<Node>>();
queue.Enqueue(0, new Path<Node>(start));
while (!queue.IsEmpty)
{
var path = queue.Dequeue();
if (closed.Contains(path.LastStep))
continue;
if (path.LastStep.Equals(destination))
return path;
closed.Add(path.LastStep);
foreach (Node n in path.LastStep.Neighbours)
{
double d = distance(path.LastStep, n);
if (n.Equals(destination))
d = 0;
var newPath = path.AddStep(n, d);
queue.Enqueue(newPath.TotalCost + estimate(n), newPath);
}
}
return null;
}
/// <summary>
/// Finds the distance between two points on a 2D surface.
/// </summary>
/// <param name="x1">The IntPoint on the x-axis of the first IntPoint</param>
/// <param name="x2">The IntPoint on the x-axis of the second IntPoint</param>
/// <param name="y1">The IntPoint on the y-axis of the first IntPoint</param>
/// <param name="y2">The IntPoint on the y-axis of the second IntPoint</param>
/// <returns></returns>
public static long Distance2D(long x1, long y1, long x2, long y2)
{
// ______________________
//d = √ (x2-x1)^2 + (y2-y1)^2
//
//Our end result
long result = 0;
//Take x2-x1, then square it
double part1 = Math.Pow((x2 - x1), 2);
//Take y2-y1, then sqaure it
double part2 = Math.Pow((y2 - y1), 2);
//Add both of the parts together
double underRadical = part1 + part2;
//Get the square root of the parts
result = (long)Math.Sqrt(underRadical);
//Return our result
return result;
}
/// <summary>
/// Finds the distance between two points on a 2D surface.
/// </summary>
/// <param name="x1">The IntPoint on the x-axis of the first IntPoint</param>
/// <param name="x2">The IntPoint on the x-axis of the second IntPoint</param>
/// <param name="y1">The IntPoint on the y-axis of the first IntPoint</param>
/// <param name="y2">The IntPoint on the y-axis of the second IntPoint</param>
/// <returns></returns>
public static int Distance2D(int x1, int y1, int x2, int y2)
{
// ______________________
//d = √ (x2-x1)^2 + (y2-y1)^2
//
//Our end result
int result = 0;
//Take x2-x1, then square it
double part1 = Math.Pow((x2 - x1), 2);
//Take y2-y1, then sqaure it
double part2 = Math.Pow((y2 - y1), 2);
//Add both of the parts together
double underRadical = part1 + part2;
//Get the square root of the parts
result = (int)Math.Sqrt(underRadical);
//Return our result
return result;
}
public static long Distance2D(Point one, Point two)
{
return AStar.Distance2D(one.X, one.Y, two.X, two.Y);
}
}
```

The PriorityQueue code:

```
class PriorityQueue<P, V>
{
private SortedDictionary<P, Queue<V>> list = new SortedDictionary<P, Queue<V>>();
public void Enqueue(P priority, V value)
{
Queue<V> q;
if (!list.TryGetValue(priority, out q))
{
q = new Queue<V>();
list.Add(priority, q);
}
q.Enqueue(value);
}
public V Dequeue()
{
// will throw if there isn’t any first element!
var pair = list.First();
var v = pair.Value.Dequeue();
if (pair.Value.Count == 0) // nothing left of the top priority.
list.Remove(pair.Key);
return v;
}
public bool IsEmpty
{
get { return !list.Any(); }
}
}
```

**And the interface that gets nearby nodes:**

```
interface IHasNeighbours<N>
{
IEnumerable<N> Neighbours { get; }
}
```

This is the part I'm having trouble effectively implementing. I can create a class capable of being used by the path finding, but finding the nearby nodes is becoming a pain. Essentially what I end up doing is creating a class that, in this case, counts as a single tile. However, in order to get all the nearby nodes, I have to pass a value into that tile that includes a list of all other tiles. This is very cumbersome and leads me to believe there must be an easier method.

Here is my implementation using a wrapper for System.Drawing.Point:

```
class TDGrid : IHasNeighbours<TDGrid>, IEquatable<TDGrid>
{
public Point GridPoint;
public List<Point> _InvalidPoints = new List<Point>();
public Size _GridSize = new Size();
public int _GridTileSize = 50;
public TDGrid(Point p, List<Point> invalidPoints, Size gridSize)
{
GridPoint = p;
_InvalidPoints = invalidPoints;
_GridSize = gridSize;
}
public TDGrid Up(int gridSize)
{
return new TDGrid(new Point(GridPoint.X, GridPoint.Y - gridSize));
}
public TDGrid Down(int gridSize)
{
return new TDGrid(new Point(GridPoint.X, GridPoint.Y + gridSize));
}
public TDGrid Left(int gridSize)
{
return new TDGrid(new Point(GridPoint.X - gridSize, GridPoint.Y));
}
public TDGrid Right(int gridSize)
{
return new TDGrid(new Point(GridPoint.X + gridSize, GridPoint.Y));
}
public IEnumerable<TDGrid> IHasNeighbours<TDGrid>.Neighbours
{
get { return GetNeighbours(this); }
}
private List<TDGrid> GetNeighbours(TDGrid gridPoint)
{
List<TDGrid> retList = new List<TDGrid>();
if (IsGridSpotAvailable(gridPoint.Up(_GridTileSize)))
retList.Add(gridPoint.Up(_GridTileSize)); ;
if (IsGridSpotAvailable(gridPoint.Down(_GridTileSize)))
retList.Add(gridPoint.Down(_GridTileSize));
if (IsGridSpotAvailable(gridPoint.Left(_GridTileSize)))
retList.Add(gridPoint.Left(_GridTileSize));
if (IsGridSpotAvailable(gridPoint.Right(_GridTileSize)))
retList.Add(gridPoint.Right(_GridTileSize));
return retList;
}
public bool IsGridSpotAvailable(TDGrid gridPoint)
{
if (_InvalidPoints.Contains(gridPoint.GridPoint))
return false;
if (gridPoint.GridPoint.X < 0 || gridPoint.GridPoint.X > _GridSize.Width)
return false;
if (gridPoint.GridPoint.Y < 0 || gridPoint.GridPoint.Y > _GridSize.Height)
return false;
return true;
}
public override int GetHashCode()
{
return GridPoint.GetHashCode();
}
public override bool Equals(object obj)
{
return this.GridPoint == (obj as TDGrid).GridPoint;
}
public bool Equals(TDGrid other)
{
return this.GridPoint == other.GridPoint;
}
}
```

The List _InvalidPoints is where I'm falling flat. I can pass this in to every TDGrid that is created but that seems like a massive waste of resources considering how simple all the rest of the code is. I know this is a lack of knowledge on my part but I haven't been able to search it down.

There must be another way to implement:

```
interface IHasNeighbours<N>
{
IEnumerable<N> Neighbours { get; }
}
```

Anyone have any ideas on this?

Edit -- Here's the path finding code:

```
public void FindPath(TDGrid start, TDGrid end)
{
AStar.FindPath<TDGrid>(start, end, (p1, p2) => { return AStar.Distance2D(p1.GridPoint, p2.GridPoint); }, (p1) => { return AStar.Distance2D(p1.GridPoint, end.GridPoint); });
}
```

`invalidPoints`

list is a set of tile locations that are not traversable (that is, that the A* search needs to route around)? Here's a thought: why not just keep a NxN array of Nodes representing every possible tile, and have each node have an attached "traversal cost" that indicates how much time it takes to cross that tile. Then your invalid tiles are just nodes with infinitely large cost (or, to make it simpler, something like`cost = int.MaxValue`

), and A* will route around them just fine. – Daniel Pryden Jun 11 '12 at 15:38