In a tower defense game, you have an NxM grid with a start, a finish, and a number of walls.
Enemies take the shortest path from start to finish without passing through any walls (they aren't usually constrained to the grid, but for simplicity's sake let's say they are. In either case, they can't move through diagonal "holes")
The problem (for this question at least) is to place up to K additional walls to maximize the path the enemies have to take. For example, for K=14
My intuition tells me this problem is NP-hard if (as I'm hoping to do) we generalize this to include waypoints that must be visited before moving to the finish, and possibly also without waypoints.
But, are there any decent heuristics out there for near-optimal solutions?
[Edit] I have posted a related question here.
I present a greedy approach and it's maybe close to the optimal (but I couldn't find approximation factor). Idea is simple, we should block the cells which are in critical places of the Maze. These places can help to measure the connectivity of maze. We can consider the vertex connectivity and we find minimum vertex cut which disconnects the start and final: (s,f). After that we remove some critical cells.
To turn it to the graph, take dual of maze. Find minimum (s,f) vertex cut on this graph. Then we examine each vertex in this cut. We remove a vertex its deletion increases the length of all s,f paths or if it is in the minimum length path from s to f. After eliminating a vertex, recursively repeat the above process for k time.
But there is an issue with this, this is when we remove a vertex which cuts any path from s to f. To prevent this we can weight cutting node as high as possible, means first compute minimum (s,f) cut, if cut result is just one node, make it weighted and set a high weight like n^3 to that vertex, now again compute the minimum s,f cut, single cutting vertex in previous calculation doesn't belong to new cut because of waiting.
But if there is just one path between s,f (after some iterations) we can't improve it. In this case we can use normal greedy algorithms like removing node from a one of a shortest path from s to f which doesn't belong to any cut. after that we can deal with minimum vertex cut.
The algorithm running time in each step is:
min-cut + path finding for all nodes in min-cut
O(min cut) + O(n^2)*O(number of nodes in min-cut)
And because number of nodes in min cut can not be greater than O(n^2) in very pessimistic situation the algorithm is O(kn^4), but normally it shouldn't take more than O(kn^3), because normally min-cut algorithm dominates path finding, also normally path finding doesn't takes O(n^2).
I guess the greedy choice is a good start point for simulated annealing type algorithms.
P.S: minimum vertex cut is similar to minimum edge cut, and similar approach like max-flow/min-cut can be applied on minimum vertex cut, just assume each vertex as two vertex, one Vi, one Vo, means input and outputs, also converting undirected graph to directed one is not hard.
it can be easily shown (proof let as an exercise to the reader) that it is enough to search for the solution so that every one of the K blockades is put on the current minimum-length route. Note that if there are multiple minimal-length routes then all of them have to be considered. The reason is that if you don't put any of the remaining blockades on the current minimum-length route then it does not change; hence you can put the first available blockade on it immediately during search. This speeds up even a brute-force search.
But there are more optimizations. You can also always decide that you put the next blockade so that it becomes the FIRST blockade on the current minimum-length route, i.e. you work so that if you place the blockade on the 10th square on the route, then you mark the squares 1..9 as "permanently open" until you backtrack. This saves again an exponential number of squares to search for during backtracking search.
You can then apply heuristics to cut down the search space or to reorder it, e.g. first try those blockade placements that increase the length of the current minimum-length route the most. You can then run the backtracking algorithm for a limited amount of real-time and pick the best solution found thus far.
I believe we can reduce the contained maximum manifold problem to boolean satisifiability and show NP-completeness through any dependency on this subproblem. Because of this, the algorithms spinning_plate provided are reasonable as heuristics, precomputing and machine learning is reasonable, and the trick becomes finding the best heuristic solution if we wish to blunder forward here.
Consider a board like the following:
..S........
#.#..#..###
...........
...........
..........F
This has many of the problems that cause greedy and gate-bound solutions to fail. If we look at that second row:
#.#..#..###
Our logic gates are, in 0-based 2D array ordered as [row][column]:
[1][4], [1][5], [1][6], [1][7], [1][8]
We can re-render this as an equation to satisfy the block:
if ([1][9] AND ([1][10] AND [1][11]) AND ([1][12] AND [1][13]):
traversal_cost = INFINITY; longest = False # Infinity does not qualify
Excepting infinity as an unsatisfiable case, we backtrack and rerender this as:
if ([1][14] AND ([1][15] AND [1][16]) AND [1][17]:
traversal_cost = 6; longest = True
And our hidden boolean relationship falls amongst all of these gates. You can also show that geometric proofs can't fractalize recursively, because we can always create a wall that's exactly N-1 width or height long, and this represents a critical part of the solution in all cases (therefore, divide and conquer won't help you).
Furthermore, because perturbations across different rows are significant:
..S........
#.#........
...#..#....
.......#..#
..........F
We can show that, without a complete set of computable geometric identities, the complete search space reduces itself to N-SAT.
By extension, we can also show that this is trivial to verify and non-polynomial to solve as the number of gates approaches infinity. Unsurprisingly, this is why tower defense games remain so fun for humans to play. Obviously, a more rigorous proof is desirable, but this is a skeletal start.
Do note that you can significantly reduce the n term in your n-choose-k relation. Because we can recursively show that each perturbation must lie on the critical path, and because the critical path is always computable in O(V+E) time (with a few optimizations to speed things up for each perturbation), you can significantly reduce your search space at a cost of a breadth-first search for each additional tower added to the board.
Because we may tolerably assume O(n^k) for a deterministic solution, a heuristical approach is reasonable. My advice thus falls somewhere between spinning_plate's answer and Soravux's, with an eye towards machine learning techniques applicable to the problem.
The 0th solution: Use a tolerable but suboptimal AI, in which spinning_plate provided two usable algorithms. Indeed, these approximate how many naive players approach the game, and this should be sufficient for simple play, albeit with a high degree of exploitability.
The 1st-order solution: Use a database. Given the problem formulation, you haven't quite demonstrated the need to compute the optimal solution on the fly. Therefore, if we relax the constraint of approaching a random board with no information, we can simply precompute the optimum for all K tolerable for each board. Obviously, this only works for a small number of boards: with V! potential board states for each configuration, we cannot tolerably precompute all optimums as V becomes very large.
The 2nd-order solution: Use a machine-learning step. Promote each step as you close a gap that results in a very high traversal cost, running until your algorithm converges or no more optimal solution can be found than greedy. A plethora of algorithms are applicable here, so I recommend chasing the classics and the literature for selecting the correct one that works within the constraints of your program.
The best heuristic may be a simple heat map generated by a locally state-aware, recursive depth-first traversal, sorting the results by most to least commonly traversed after the O(V^2) traversal. Proceeding through this output greedily identifies all bottlenecks, and doing so without making pathing impossible is entirely possible (checking this is O(V+E)).
Putting it all together, I'd try an intersection of these approaches, combining the heat map and critical path identities. I'd assume there's enough here to come up with a good, functional geometric proof that satisfies all of the constraints of the problem.
At the risk of stating the obvious, here's one algorithm
1) Find the shortest path
2) Test blocking everything node on that path and see which one results in the longest path
3) Repeat K times
Naively, this will take O(K*(V+ E log E)^2) but you could with some little work improve 2 by only recalculating partial paths.
As you mention, simply trying to break the path is difficult because if most breaks simply add a length of 1 (or 2), its hard to find the choke points that lead to big gains.
If you take the minimum vertex cut between the start and the end, you will find the choke points for the entire graph. One possible algorithm is this
1) Find the shortest path
2) Find the min-cut of the whole graph
3) Find the maximal contiguous node set that intersects one point on the path, block those.
4) Wash, rinse, repeat
3) is the big part and why this algorithm may perform badly, too. You could also try
the smallest node set that connects with other existing blocks.
finding all groupings of contiguous verticies in the vertex cut, testing each of them for the longest path a la the first algorithm
The last one is what might be most promising
If you find a min vertex cut on the whole graph, you're going to find the choke points for the whole graph.
Here is a thought. In your grid, group adjacent walls into islands and treat every island as a graph node. Distance between nodes is the minimal number of walls that is needed to connect them (to block the enemy).
In that case you can start maximizing the path length by blocking the most cheap arcs.
I have no idea if this would work, because you could make new islands using your points. but it could help work out where to put walls.
I suggest using a modified breadth first search with a K-length priority queue tracking the best K paths between each island.
i would, for every island of connected walls, pretend that it is a light. (a special light that can only send out horizontal and vertical rays of light)
Use ray-tracing to see which other islands the light can hit
say Island1 (i1) hits i2,i3,i4,i5 but doesn't hit i6,i7..
then you would have line(i1,i2), line(i1,i3), line(i1,i4) and line(i1,i5)
Mark the distance of all grid points to be infinity. Set the start point as 0.
Now use breadth first search from the start. Every grid point, mark the distance of that grid point to be the minimum distance of its neighbors.
But.. here is the catch..
every time you get to a grid-point that is on a line() between two islands, Instead of recording the distance as the minimum of its neighbors, you need to make it a priority queue of length K. And record the K shortest paths to that line() from any of the other line()s
This priority queque then stays the same until you get to the next line(), where it aggregates all priority ques going into that point.
You haven't showed the need for this algorithm to be realtime, but I may be wrong about this premice. You could then precalculate the block positions.
If you can do this beforehand and then simply make the AI build the maze rock by rock as if it was a kind of tree, you could use genetic algorithms to ease up your need for heuristics. You would need to load any kind of genetic algorithm framework, start with a population of non-movable blocks (your map) and randomly-placed movable blocks (blocks that the AI would place). Then, you evolve the population by making crossovers and transmutations over movable blocks and then evaluate the individuals by giving more reward to the longest path calculated. You would then simply have to write a resource efficient path-calculator without the need of having heuristics in your code. In your last generation of your evolution, you would take the highest-ranking individual, which would be your solution, thus your desired block pattern for this map.
Genetic algorithms are proven to take you, under ideal situation, to a local maxima (or minima) in reasonable time, which may be impossible to reach with analytic solutions on a sufficiently large data set (ie. big enough map in your situation).
You haven't stated the language in which you are going to develop this algorithm, so I can't propose frameworks that may perfectly suit your needs.
Note that if your map is dynamic, meaning that the map may change over tower defense iterations, you may want to avoid this technique since it may be too intensive to re-evolve an entire new population every wave.
I'm not at all an algorithms expert, but looking at the grid makes me wonder if Conway's game of life might somehow be useful for this. With a reasonable initial seed and well-chosen rules about birth and death of towers, you could try many seeds and subsequent generations thereof in a short period of time.
You already have a measure of fitness in the length of the creeps' path, so you could pick the best one accordingly. I don't know how well (if at all) it would approximate the best path, but it would be an interesting thing to use in a solution.
Related
I was wondering about an optimisation problem related to graph's exploration :
Suppose we have a connected weighted graph, and each vertex has between 1 and 4 connections with other vertices. Now let's say some vertices contain chocolate ,and we put on that graph at two different vertices two students both of them controlled by two AIs that have access to the position of the chocolates, the position of the other student and the graph, and at each turn, both of them can move to a connected vertex (and need K moves if the weigh of the edge is K). Finally, if a student is on a vertex containing chocolate he eats it.
My question : What would the best algorithm for the AI so that the student controlled will eat more chocolate then the other ?
Thank you .
The best approach to this would likely be using cost analysis and heuristics.
Your bot has 1-4 choices it can make, so you should consider each one. What's the benefit of going up? What's the cost? If you take value as benefit - cost, then you should choose the most valuable option.
So... How do you even calculate benefit and cost, anyways? You've outlined a few conditions already. The K value is a cost. Whether there is a chocolate there is a benefit. Maybe analyze the number of chocolates adjacent to a given vertex?
But wait! You know your enemy's position, and your enemy knows yours! If you move in a given direction, it'll influence their move (If they're smart.) So you'll have to look ahead and analyze what your enemy will probably do in response to you. Chess solvers use breadth-first lookahead to plan out the best possible move via this exact system. Unfortunately, your problem is unbounded - There is no true win condition. So your bot will look ahead indefinitely (or, until it runs out of memory, anyways.) This is a problem, because calculations take time. Chess solvers get around this by imposing a time limit. They take the best move they've found by the time they run out of time.
Now, I've given you a general framework to work within. You still need to assemble it. Part of making heuristics is weighing your costs and benefits. Maybe the cost of K is insignificant compared to the benefit of getting a chocolate? Maybe it isnt? Use constant coefficients to weigh the costs and benefits.
As for finding your way through the grid, I'd take a look at Dijkstra's algorithm or A* to move.
Oh, and before I forget, here's the wikipedia article on graph traversal. You may find it useful.
I have been using Dijkstra Algorithm to find the shortest path in the Graph API which is given by the Princeton University Algorithm Part 2, and I have figured out how to find the path with Chebyshev Distance.
Even though Chebyshev can move to any side of the node with the cost of only 1, there is no impact on the Total Cost, but according to the graph, the red circle, why does the path finding line moves zigzag without moving straight?
Will the same thing will repeat if I use A* Algorithm?
If you want to prioritize "straight lines" you should take the direction of previous step into account. One possible way is to create a graph G'(V', E') where V' consists of all neighbour pairs of vertices. For example, vertex v = (v_prev, v_cur) would define a vertex in the path where v_cur is the last vertex of the path and v_prev is the previous vertex. Then on "updating distances" step of the shortest path algorithm you could choose the best distance with the best (non-changing) direction.
Also we can add additional property to the distance equal to the number of changing a direction and find the minimal distance way with minimal number of direction changes.
It shouldn't be straight in particular, according to Dijkstra or A*, as you say it has no impact on the total cost. I'll assume, by the way, that you want to prevent useless zig-zagging in particular, and have no particular preference in general for a move that goes in the same direction as the previous move.
Dijkstra and A* do not have a built-in dislike for "weird paths", they only explicitly care about the cost, implicitly that means they also care about how you handle equal costs. There are a couple of things you can do about that:
Use tie-breaking to make them prefer straight moves whenever two nodes have equal cost (G or F, depending on whether you're doing Dijkstra or A*). This gives some trouble around obstacles because two choices that eventually lead to equal-length paths do not necessarily have the same F score, so they might not get tie-broken. It'll never give you a sub-optimal path though.
Slightly increase your diagonal cost, it doesn't have to be a whole lot, say 10 for straight and 11 for diagonal. This will just avoid any diagonal move that isn't a shortcut. But obviously: if that doesn't match the actual cost, you can now find sub-optimal paths. The bigger the cost difference, the more that will happen. In practice it's relatively rare, and paths have to be long enough (accumulating enough cost-difference that it becomes worth an entire extra move) before it happens.
I am using A* in order to solve the Asymmetric Traveling Salesman problem.
My state representation has 4 variables:
1 - Visited cities (List)
2 - Unvisitied cities (List)
3 - Current City (Integer)
4 - Current Cost (Integer)
However, even tho I find many path-construction algorithms such as Nearest Neighbor, k-opt and so on, I can't find an heuristic suitable for A*, which is, a h(n) function that takes a state as input and returns an integer corresponding to that state's quality.
So my question is, are there such heuristics? Any recommendations?
Thanks in advance
The weight of the minimum spanning tree of the subgraph that contains all unvisited vertices and the current vertex is a lower bound for the cost to finish the current path. It can be used with the A* algorithm as it can't overestimate the remaining distance (otherwise, the weight of the remaining path is smaller than the weight of minimum spanning tree and it spans the given vertices, which is a contradiction).
I've never tried it though so I don't know how well it'll work in practice.
There always are: h(n) = 0 always works. It is useless, turning A* into Dijkstra, but it's definitely admissible.
An other obvious one: let h(n) be the shortest edge from the current city back to the beginning. Still a huge underestimation, but at least it's not necessarily zero. It's obviously valid, the loop has to be closed eventually and (given this partial route) there is no shorter way to do it.
You can be a bit more clever here, for example you could use linear programming (make two variables for each edge, one for each direction, then for every city make a constraint forcing the sum of entering edges to be 1 and a constraint forcing the sum of exiting edges to be one, weights are obviously the distances) to find an underestimation of the length from the current node back to the beginning while touching every city in the set of unvisited cities. Of course if you're doing that, you might as well drop A* and just use the usual integer linear programming tricks. A* doesn't seem like a good fit here (especially in the beginning, the branching factor is too high and the heuristics won't guide it enough yet), but I haven't tried this so who knows.
Also, given the solution from the LP, you can improve it a lot by using some simple tricks (and some advanced tricks that whole books have been written about, but let's not go there, read the books if you want to know). For example, one thing the LP likes to do is form lots of little triangles. This will satisfy the degree constraints everywhere locally and keeps everything nice and short. But it's not a tour, and forcing it be more like a tour will make the heuristic higher=better. To remove the sub-tours, you can detect them in the fractional solution and then force the number of entries to the subgraph to be at least 1 (it may have to become more than 1 at some point, so don't force it to be exactly 1) and force the number of exits to be at least 1, by adding the corresponding constraints and solving again. There are many more tricks, but this should already give a very reasonable heuristic, much closer to the actual cost than using any of the overestimating heuristics and dividing them by their worst case overestimation factor. The problem with those is that usually the heuristic is pretty good, much better than their worst case factor, and then dividing by the worst case factor really kills the quality of the heuristic.
Most of the time when implementing a pathfinding algorithm such as A*, we seek to minimize the travel cost along the path. We could also seek to find the optimal path with the fewest number of turns. This could be done by, instead of having a grid of location states, having a grid of location-direction states. For any given location in the old grid, we would have 4 states in that spot representing that location moving left, right, up, or down. That is, if you were expanding to a node above you, you would actually be adding the 'up' state of that node to the priority queue, since we've found the quickest route to this node when going UP. If you were going that direction anyway, we wouldnt add anything to the weight. However, if we had to turn from the current node to get to the expanded node, we would add a small epsilon to the weight such that two shortest paths in distance would not be equal in cost if their number of turns differed. As long as epsilon is << cost of moving between nodes, its still the shortest path.
I now pose a similar problem, but with relaxed constraints. I no longer wish to find the shortest path, not even a path with the fewest turns. My only goal is to find a path of ANY length with numTurns <= n. To clarify, the goal of this algorithm would be to answer the question:
"Does there exist a path P from locations A to B such that there are fewer than or equal to n turns?"
I'm asking whether using some sort of greedy algorithm here would be helpful, since I do not require minimum distance nor turns. The problem is, if I'm NOT finding the minimum, the algorithm may search through more squares on the board. That is, normally a shortest path algorithm searches the least number of squares it has to, which is key for performance.
Are there any techniques that come to mind that would provide an efficient way (better or same as A*) to find such a path? Again, A* with fewest turns provides the "optimal" solution for distance and #turns. But for my problem, "optimal" is the fastest way the function can return whether there is a path of <=n turns between A and B. Note that there can be obstacles in the path, but other than that, moving from one square to another is the same cost (unless turning, as mentioned above).
I've been brainstorming, but I can not think of anything other than A* with the turn states . It might not be possible to do better than this, but I thought there may be a clever exploitation of my relaxed conditions. I've even considered using just numTurns as the cost of moving on the board, but that could waste a lot of time searching dead paths. Thanks very much!
Edit: Final clarification - Path does not have to have least number of turns, just <= n. Path does not have to be a shortest path, it can be a huge path if it only has n turns. The goal is for this function to execute quickly, I don't even need to record the path. I just need to know whether there exists one. Thanks :)
Im looking for an algorithm to be used in a racing game Im making. The map/level/track is randomly generated so I need to find two locations, start and goal, that makes use of the most of the map.
The algorithm is to work inside a two dimensional space
From each point, one can only traverse to the next point in four directions; up, down, left, right
Points can only be either blocked or nonblocked, only nonblocked points can be traversed
Regarding the calculation of distance, it should not be the "bird path" for a lack of a better word. The path between A and B should be longer if there is a wall (or other blocking area) between them.
Im unsure on where to start, comments are very welcome and proposed solutions are preferred in pseudo code.
Edit: Right. After looking through gs's code I gave it another shot. Instead of python, I this time wrote it in C++. But still, even after reading up on Dijkstras algorithm, the floodfill and Hosam Alys solution, I fail to spot any crucial difference. My code still works, but not as fast as you seem to be getting yours to run. Full source is on pastie. The only interesting lines (I guess) is the Dijkstra variant itself on lines 78-118.
But speed is not the main issue here. I would really appreciate the help if someone would be kind enough to point out the differences in the algorithms.
In Hosam Alys algorithm, is the only difference that he scans from the borders instead of every node?
In Dijkstras you keep track and overwrite the distance walked, but not in floodfill, but thats about it?
Assuming the map is rectangular, you can loop over all border points, and start a flood fill to find the most distant point from the starting point:
bestSolution = { start: (0,0), end: (0,0), distance: 0 };
for each point p on the border
flood-fill all points in the map to find the most distant point
if newDistance > bestSolution.distance
bestSolution = { p, distantP, newDistance }
end if
end loop
I guess this would be in O(n^2). If I am not mistaken, it's (L+W) * 2 * (L*W) * 4, where L is the length and W is the width of the map, (L+W) * 2 represents the number of border points over the perimeter, (L*W) is the number of points, and 4 is the assumption that flood-fill would access a point a maximum of 4 times (from all directions). Since n is equivalent to the number of points, this is equivalent to (L + W) * 8 * n, which should be better than O(n2). (If the map is square, the order would be O(16n1.5).)
Update: as per the comments, since the map is more of a maze (than one with simple obstacles as I was thinking initially), you could make the same logic above, but checking all points in the map (as opposed to points on the border only). This should be in order of O(4n2), which is still better than both F-W and Dijkstra's.
Note: Flood filling is more suitable for this problem, since all vertices are directly connected through only 4 borders. A breadth first traversal of the map can yield results relatively quickly (in just O(n)). I am assuming that each point may be checked in the flood fill from each of its 4 neighbors, thus the coefficient in the formulas above.
Update 2: I am thankful for all the positive feedback I have received regarding this algorithm. Special thanks to #Georg for his review.
P.S. Any comments or corrections are welcome.
Follow up to the question about Floyd-Warshall or the simple algorithm of Hosam Aly:
I created a test program which can use both methods. Those are the files:
maze creator
find longest distance
In all test cases Floyd-Warshall was by a great magnitude slower, probably this is because of the very limited amount of edges that help this algorithm to achieve this.
These were the times, each time the field was quadruplet and 3 out of 10 fields were an obstacle.
Size Hosam Aly Floyd-Warshall
(10x10) 0m0.002s 0m0.007s
(20x20) 0m0.009s 0m0.307s
(40x40) 0m0.166s 0m22.052s
(80x80) 0m2.753s -
(160x160) 0m48.028s -
The time of Hosam Aly seems to be quadratic, therefore I'd recommend using that algorithm.
Also the memory consumption by Floyd-Warshall is n2, clearly more than needed.
If you have any idea why Floyd-Warshall is so slow, please leave a comment or edit this post.
PS: I haven't written C or C++ in a long time, I hope I haven't made too many mistakes.
It sounds like what you want is the end points separated by the graph diameter. A fairly good and easy to compute approximation is to pick a random point, find the farthest point from that, and then find the farthest point from there. These last two points should be close to maximally separated.
For a rectangular maze, this means that two flood fills should get you a pretty good pair of starting and ending points.
I deleted my original post recommending the Floyd-Warshall algorithm. :(
gs did a realistic benchmark and guess what, F-W is substantially slower than Hosam Aly's "flood fill" algorithm for typical map sizes! So even though F-W is a cool algorithm and much faster than Dijkstra's for dense graphs, I can't recommend it anymore for the OP's problem, which involves very sparse graphs (each vertex has only 4 edges).
For the record:
An efficient implementation of Dijkstra's algorithm takes O(Elog V) time for a graph with E edges and V vertices.
Hosam Aly's "flood fill" is a breadth first search, which is O(V). This can be thought of as a special case of Dijkstra's algorithm in which no vertex can have its distance estimate revised.
The Floyd-Warshall algorithm takes O(V^3) time, is very easy to code, and is still the fastest for dense graphs (those graphs where vertices are typically connected to many other vertices). But it's not the right choice for the OP's task, which involves very sparse graphs.
Raimund Seidel gives a simple method using matrix multiplication to compute the all-pairs distance matrix on an unweighted, undirected graph (which is exactly what you want) in the first section of his paper On the All-Pairs-Shortest-Path Problem in Unweighted Undirected Graphs
[pdf].
The input is the adjacency matrix and the output is the all-pairs shortest-path distance matrix. The run-time is O(M(n)*log(n)) for n points where M(n) is the run-time of your matrix multiplication algorithm.
The paper also gives the method for computing the actual paths (in the same run-time) if you need this too.
Seidel's algorithm is cool because the run-time is independent of the number of edges, but we actually don't care here because our graph is sparse. However, this may still be a good choice (despite the slightly-worse-than n^2 run-time) if you want the all pairs distance matrix, and this might also be easier to implement and debug than floodfill on a maze.
Here is the pseudocode:
Let A be the nxn (0-1) adjacency matrix of an unweighted, undirected graph, G
All-Pairs-Distances(A)
Z = A * A
Let B be the nxn matrix s.t. b_ij = 1 iff i != j and (a_ij = 1 or z_ij > 0)
if b_ij = 1 for all i != j return 2B - A //base case
T = All-Pairs-Distances(B)
X = T * A
Let D be the nxn matrix s.t. d_ij = 2t_ij if x_ij >= t_ij * degree(j), otherwise d_ij = 2t_ij - 1
return D
To get the pair of points with the greatest distance we just return argmax_ij(d_ij)
Finished a python mockup of the dijkstra solution to the problem.
Code got a bit long so I posted it somewhere else: http://refactormycode.com/codes/717-dijkstra-to-find-two-points-furthest-away-from-each-other
In the size I set, it takes about 1.5 seconds to run the algorithm for one node. Running it for every node takes a few minutes.
Dont seem to work though, it always displays the topleft and bottomright corner as the longest path; 58 tiles. Which of course is true, when you dont have obstacles. But even adding a couple of randomly placed ones, the program still finds that one the longest. Maybe its still true, hard to test without more advanced shapes.
But maybe it can at least show my ambition.
Ok, "Hosam's algorithm" is a breadth first search with a preselection on the nodes.
Dijkstra's algorithm should NOT be applied here, because your edges don't have weights.
The difference is crucial, because if the weights of the edges vary, you need to keep a lot of options (alternate routes) open and check them with every step. This makes the algorithm more complex.
With the breadth first search, you simply explore all edges once in a way that garantuees that you find the shortest path to each node. i.e. by exploring the edges in the order you find them.
So basically the difference is Dijkstra's has to 'backtrack' and look at edges it has explored before to make sure it is following the shortest route, while the breadth first search always knows it is following the shortest route.
Also, in a maze the points on the outer border are not guaranteed to be part of the longest route.
For instance, if you have a maze in the shape of a giant spiral, but with the outer end going back to the middle, you could have two points one at the heart of the spiral and the other in the end of the spiral, both in the middle!
So, a good way to do this is to use a breadth first search from every point, but remove the starting point after a search (you already know all the routes to and from it).
Complexity of breadth first is O(n), where n = |V|+|E|. We do this once for every node in V, so it becomes O(n^2).
Your description sounds to me like a maze routing problem. Check out the Lee Algorithm. Books about place-and-route problems in VLSI design may help you - Sherwani's "Algorithms for VLSI Physical Design Automation" is good, and you may find VLSI Physical Design Automation by Sait and Youssef useful (and cheaper in its Google version...)
If your objects (points) do not move frequently you can perform such a calculation in a much shorter than O(n^3) time.
All you need is to break the space into large grids and pre-calculate the inter-grid distance. Then selecting point pairs that occupy most distant grids is a matter of simple table lookup. In the average case you will need to pair-wise check only a small set of objects.
This solution works if the distance metrics are continuous. Thus if, for example there are many barriers in the map (as in mazes), this method might fail.