# 2D waypoint pathfinding: combinations of WPs to go from curLocation to targetLocation

Please take a moment to understand my situation. If it is not comprehendable, please tell me in a comment.

I have an ArrayList of Waypoints. These waypoints are not in any order. A waypoint has the following properties:
`{int type, float z, float y, float x, float rotation}`

This applies to a 3 dimensional world, but since my pathfinding should not care about height (and thus treat the world as a 2 dimensional one), the y value is ignored. Rotation is not of importance for this question.

• In this 2 dimensional world, the x represents the x axis and the z represents the y axis.
• If x increases, the object in the world moves east. If x decreases, the object in the world moves west.
• If z increases, the object in the world moves north. If z decreases, the object in the world moves south.

Thus, these "new" waypoints can be simplified to: `waypoint = {float x, float y}`.

Now, these waypoints represent the X-axis (x) and Y-axis (z) locations of an object. Moreover, there is a current location: `curLocation = {float x, float y}` and a target location: `tarLocation = {float x, float y}`.

This is what I want to get:
All combinations of waypoints (aka: paths or routes) that will lead from `curLocation` to `tarLocation` under the following strict conditions:

1. The distance inbetween each waypoint may not be bigger than `(float) maxInbetweenDistance`. This includes the initial distance from `curLocation` to the first waypoint and the distance from the last waypoint to `tarLocation`. If no such combination of waypoints is possible, null should be returned.
2. When multiple waypoints are found within `maxInbetweenDistance` from a waypoint that lead towards the target waypoint, the closest waypoint should be chosen (even better would be if an alternative waypoint that is slightly further away would result in a new path with a longer distance that is also returned).
3. The order of returned waypoint combinations (paths) should be from shortest route (minimum distance) to longest route (maximum distance)

1. This is the only thing I need to do AI/pathfinding wise, which is why I do not wish to use a full blown pathfinding or AI framework. I believe one function should be able to handle the above.
2. If returning all possible combinations of waypoints causes too much overhead, it'd also be fine if one can specify a maximum amount of combinations (but still ordered from closest to furthest). Eg. the 5 closest paths.

How would I achieve this? Any feedback is appreciated.

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I think your solution is to start with Dijkstra's Algorithm to find the shortest path first. You can consider your waypoints to be a connected graph where nodes are connected if they are close enough in the xy plane then apply Dijkstra (there are many example code listings online).

Now you have the shortest path through your graph from start to finish, which will be composed of N edges of the graph.

You would next need to create N new graphs, each just like the first, but with one segment of your shortest route un-connected. Find the shortest routes from start to finish on these modified graphs. Now you have N+1 routes which you can sort by length.

Repeat this until you have found enough paths for your needs, or there are no unranked paths left.

I haven't found a name for this technique, but it is described as a modification to Dijkstra here.

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after looking at the algorithm, I am not sure how I can make it only use waypoints that are not too far from each other. Or should I generate these paths manually? Basically, all I have is this arraylist with waypoints - where should I start? – Tom Mar 4 '11 at 22:17
Start by preparing the graph. A graph is just a set of nodes, and a set of edges (which are just pairs of nodes with a "weight", ie length in your case). This is easily represented by an "adjacency matrix" as described by Throwback1986. en.wikipedia.org/wiki/Adjacency_matrix – Matthew Gilliard Mar 4 '11 at 22:23

If your waypoints possess connectivity, you should take a look at Dijkstra's shortest path algorithm. The first couple of google hits even lists an implementation in Java. (I can't tell if connectivity is known from the post, but it does contain the "graph-algorithm" tag, so I'll assume so). As the name suggests, this method give you a shortest path between the two nodes.

Your constraints are challenging, as is the need for all possible combinations of paths under those constraints. Again - assuming connectivity exists - your node adjacency matrix can enforce your maxInbetweenDistance rule. Likewise, you can use this matrix in obtaining the "next best" solutions. Once the optimal path is known, you can mark that path (or elements of it) as unavailable, then re-run Dijkstra's algorithm. By repeating this process, you can obtain a set of increasingly sub-optimal paths.

As a matter of convention: in most computational geometry problems, Z is the height, and the horizontal plane is formed by the XY axes.

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Thanks, someone else added the graph-algorithm tag. I am not sure what exactly you mean with connectivity, so I suppose it does not exist (?). – Tom Mar 4 '11 at 20:25
Connectivity is just the property that some nodes are connected to others. In other words there are some nodes which you can't get to in one hop, and some that you can. Your first strict condition implies that you do have a connected graph. – Matthew Gilliard Mar 4 '11 at 20:35
@mjg123, well I guess that all nodes that are near each other should be "connected". However, nothing like that has been set or anything at the moment. – Tom Mar 4 '11 at 20:36
That said, Dijkstra's algorithm will tell you only the shortest path, it won't give you a list of short paths in order of length. – Matthew Gilliard Mar 4 '11 at 20:39
@mjg123 that is alright, since I can repeat the process without the earlier path if I need another option. Thus far though I have only found a complete implementation in a rather big library (JUNG). – Tom Mar 4 '11 at 20:44

Well the easiest to implement would probably be creating an ArrayList of paths, which would be in turn an ArrayList of waypoints, that contains ALL possible paths, then using a recursive function to return whether each path is Valid or not given the starting and finishing point values, and the max distance, and if a path is not valid remove it from the list. The next step would be going through each of the paths that is left and ordering them from shortest total distance to shortest. This would be the brute force method of getting what you want, so the least efficient one possible. When I get home tonight I will repost if some one already hasn't with a more efficient method for doing this in java.

Edit: if the brute force method is too much, the list of waypoints will have to be sorted some how, the best way is probably to sort them initially based on distance from the starting point.

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Interesting, but I'm afraid that is indeed too much brute force like, as it would create an insane amount of possibilities (imagine forming combinations with 500 waypoints). I am looking forward to your update though (if applicable). Thanks. – Tom Mar 4 '11 at 19:42
If you have 500 nodes then this is a difficult problem with any technique! Especially as you don't seem to have ruled out paths which have loops (maybe, I'm not sure I understand condition #2) – Matthew Gilliard Mar 4 '11 at 20:41
@mjg123 #2 simply states that it should pick the shortest route. I understand it is much easier to only find the shorest path. I believe this would be fine as well (because I can repeat the process without the returned path to find eg. the second shortest path). – Tom Mar 4 '11 at 21:33
Then you have your solution :) – Matthew Gilliard Mar 4 '11 at 21:37
@mjg123, I am not quite sure whether I understand the algorithm's usage. I will read more about it and accept an answer if it is indeed what I need. – Tom Mar 4 '11 at 21:51