If the original algorithm was BFS, you are looking for the smallest of the shortest paths where "smallest" is according to the lexicographic order induced by some total order `Ord`

on the edges (and of course "shortest" is according to path length).

The idea of tweaking weights suggested by amit is a natural one, but I don't think it is very practical because the weights would need to have a number of bits comparable to the length of a path to avoid discarding information, which would make the algorithm orders of magnitude slower.

Thankfully this can still be done with two simple and inexpensive modifications to A*:

- Once we reach the goal, instead of returning an arbitrary shortest path to the goal, we should continue visiting nodes until the path length increases, so that we visit all nodes that belong to a shortest path.
- When reconstructing the path, we build the set of nodes that contribute to the shortest paths. This set has a DAG structure when considering all shortest path edges, and it is now easy to find the lexicography smallest path from
`start`

to `goal`

in this DAG, which is the desired solution.

Schematically, classic A* is:

```
path_length = infinity for every node
path_length[start] = 0
while score(goal) > minimal score of unvisited nodes:
x := any unvisited node with minimal score
mark x as visited
for y in unvisited neighbors of x:
path_length_through_x = path_length[x] + d(x,y)
if path_length[y] > path_length_through_x:
path_length[y] = path_length_through_x
ancestor[y] = x
return [..., ancestor[ancestor[goal]], ancestor[goal], goal]
```

where `score(x)`

stands for `path_length[x] + heuristic(x, goal)`

.

We simply turn the strict `while`

loop inequality into a non-strict one and add a path reconstruction phase:

```
path_length = infinity for every node
path_length[start] = 0
while score(goal) >= minimal score of unvisited nodes:
x := any unvisited node with minimal score
mark x as visited
for y in unvisited neighbors of x:
path_length_through_x = path_length[x] + d(x,y)
if path_length[y] > path_length_through_x:
path_length[y] = path_length_through_x
optimal_nodes = [goal]
for every x in optimal_nodes: // note: we dynamically add nodes in the loop
for y in neighbors of x not in optimal_nodes:
if path_length[x] == path_length[y] + d(x,y):
add y to optimal_nodes
path = [start]
x = start
while x != goal:
z = undefined
for y in neighbors of x that are in optimal_nodes:
if path_length[y] == path_length[x] + d(x,y):
z = y if (x,y) is smaller than (x,z) according to Ord
x = z
append x to path
return path
```

Warning: to quote Knuth, I have only proven it correct, not tried it.

As for the performance impact, it should be minimal: the search loop only visits nodes with a score that is 1 unit higher than classic A*, and the reconstruction phase is quasi-linear in the number of nodes that belong to a shortest path. The impact is smaller if, as you imply, there is only one shortest path in most cases. You can even optimize for this special case e.g. by remembering an `ancestor`

node as in the classic case, which you set to a special error value when there is more than one ancestor (that is, when `path_length[y] == path_length_through_x`

). Once the search loop is over, you attempt to retrieve a path through `ancestor`

as in classic A*; you only need to execute the full path reconstruction if an error value was encountered when building the path.

heuristicA* uses. In your case - I assume euclidean/manhattan distance. Note that if for example you set`h(v) in [0,1]`

- A* will behave exactly like BFS, except the last step.. – amit Jul 17 '12 at 15:49behavelike BFS, but that's completely useless to me. I'd like it tobehavelike A*(not lose the speed benefits), but generate the same path as BFS. I've gotten it to work in 99.9% of the cases, but the above case fails. Is there really no way to get the same path in the above maze? – BlueRaja - Danny Pflughoeft Jul 17 '12 at 15:52`w(u,v) = 1 + f(u)*prio(u,v)`

such that: (1) the total of additions to all edges combined does not exceed 1. (2)`f(u)`

is calculated based on the distance (heuristic maybe?) from the source, and is monotonically decreasing, such that each f(u) is "more important" then all the nodes that will follow it in shortest a path to the target [probably will have the zeno property and decay exponentially]. However I cannot think of a way to prove it works, and also suspect it still might misses some details. – amit Jul 17 '12 at 16:01