# A* admissible heuristics on a grid with teleporters?

Suppose that you have a 2D grid of cells, some of which are filled in with walls. Characters can take a step from one square to any square that is one step horizontal or vertical from it, but cannot cross walls.

Given a start position and an end position, we can find the shortest path from the start position to the end position by using the A* algorithm with an admissible heuristic. In this current setup, the Manhattan distance would be admissible, since it never overestimates the distance to the destination.

Now suppose that in addition to walls, the world has pairs of teleporters. Stepping onto a teleporter immediately transports a character to the linked teleporter. The existence of teleporters breaks the admissible heuristic given above, since it might be possible to get to the destination faster than taking the optimal Manhattan distance walk by using a teleporter to cut down on the distance. For example, consider this linear world with teleporters marked T, start position marked S, and end position marked E:

``````T . S . . . . . . . . . . . . . E . T
``````

Here, the best route is to walk to the teleporter on the left, then take two steps to the left.

My question is this: what is a good admissible heuristic for A* in a grid world with teleporters?

Thanks!

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The distance to the closest teleporter seems to be one obvious choice. – Vaughn Cato Jan 20 '13 at 19:28
@VaughnCato the end could be closer, but that's easy to fix with an extra min – harold Jan 20 '13 at 19:31
@templatetypedef Is that part of some online programming contest/automatic solution judging system? If so, can you give us a link so we can join :) ? – us2012 Jan 20 '13 at 20:04
@us2012- No, this is just a question I've been thinking about on and off for the past month after playing Lode Runner. :-) – templatetypedef Jan 20 '13 at 20:24

Form a graph of the teleporters:

• You have a node for each teleporter and a node for the end position.
• You have an edge connecting each node to each other node, forming a fully connected graph.
• For the edge weights, use the Manhattan distance between each node's destination cell (the one you go to when you enter the teleporter) and all the other nodes.

Use Dijkstra's algorithm to calculate the shortest distance from each node to the end.

You can now use the minimum of the distance between a particular position and all the nodes plus the pre-calculated distance from the node to the end as a heuristic function. Dijkstra's algorithm only has to be run once as a pre-processing step. However, if the number of teleporters is a large perecentage of the number of cells, you may not get any benefit over using a simpler heuristic function.

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That makes no sense, use Dijkatra's algorithm is basically running A* with `h(x,y) =0` as "pre-processing" P.S. if any - use floyd-warshall algorithm, you need the distance for each pair (x,y) – amit Jan 20 '13 at 19:43
@amit: You only need to find the distance to the end point, not the distance between every pair. – Vaughn Cato Jan 20 '13 at 19:47
My own two cents' worth: I was planning on testing this out in a static world where precomputation is totally reasonable. I actually like this two-layer approach! – templatetypedef Jan 21 '13 at 5:36
@WolframH: Because it is a heuristic function, you only have to make sure you never overestimate the actual distance. The distance without the walls will never be greater than the distance with the walls. – Vaughn Cato Feb 25 '13 at 0:59
@VaughnCato: Thanks, I get it now. Dijkstra, which itself doesn't use heuristics, is fed with non-overestimated heuristic values, and thus yields output (which is exact for the input to Dijkstra) that is a non-overestimated heuristic for the original problem. Nice, +1. – WolframH Feb 25 '13 at 10:22

If there aren't too many teleporters in your world, I would try the following heuristic, where `MHD(a,b)` is Manhattan distance between cell `a` and `b` and `T(i)` is the teleporter nearest to cell `i`:

``````h(x,y) = min( MHD(x,y), MHD(x,T(x)) + MHD(T(y),y) )
``````
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+1, that what I had in mind as well. I took the liberty to change `d*(x,y)` to `h(x,y)`, at least AFAIK it is the convention character to denote heuristic value. – amit Jan 20 '13 at 19:33
@nhahtdh: It is still admissible, his approach might be overpredicting - it takes the closest teleported to the source and the closest to the destination, as far as I see it - it cannot under-predict the distance. – amit Jan 20 '13 at 19:36
@amit: nhahtdh was right. Admissibility requires never overestimating, not never underestimating. – us2012 Jan 20 '13 at 19:38
No, it requires never underestimating. `h(x,y) = 0 (for all x,y)` is an admissible heuristic function.. though not very informative one. – amit Jan 20 '13 at 19:38
@amit: Yeah, `h(x,y)=0` is admissible because it always underestimates. You are confusing something here, I fear. – us2012 Jan 20 '13 at 19:40