# Floyd-Warshall: all shortest paths

I've implemented Floyd Warshall to return the distance of the shortest path between every pair of nodes/vertices and to return to me a (but only one) shortest path between each of these pairs. Is there anyway to get it to return every shortest path (when there are multiple that are tied for shortest) for every pair of nodes? (just want to know if I'm wasting my time trying)

-
save all the "shortest-paths" in a `HashMap` with `key=path-length` and `value={set of shortest paths at this length}`. Save the shotest-path length in a separate variable and after your algorithm is done, just pull the minimum value from the `HashMap`. –  alfasin Jul 6 '12 at 22:35

If you just need the count of how many different shortest path exist, you can keep a `count` array in addition to the `shortestPath` array. Here's is a quick modification of the pseudocode from wiki.

``````procedure FloydWarshall ()
for k := 1 to n
for i := 1 to n
for j := 1 to n
if path[i][j] == path[i][k]+path[k][j] and k != j and k != i
count[i][j] += 1;
else if path[i][j] > path[i][k] + path[k][j]
path[i][j] = path[i][k] + path[k][j]
count[i][j] = 1
``````

If you need a way to find all the paths, you can store a `vector/arraylist` like structure for each pair to expand and collapse. Here is a modification of the pseudocode from the same wiki.

``````procedure FloydWarshallWithPathReconstruction ()
for k := 1 to n
for i := 1 to n
for j := 1 to n
if path[i][k] + path[k][j] < path[i][j]
path[i][j] := path[i][k]+path[k][j];
next[i][j].clear()
next[i][j].push_back(k) // assuming its a c++ vector
else if path[i][k] + path[k][j] == path[i][j] and k != j and k != i
next[i][j].push_back(k)
``````

Note: if `k==j` or `k==i`, that means, you're checking either `path[i][i]+path[i][j]` or `path[i][j]+path[j][j]`, both should be equal to `path[i][j]` and that does not get pushed into `next[i][j]`.

Path reconstruction should be modified to handle the `vector`. The count in this case would be each `vector`'s size. Here is a modification of the pseudocode (python) from the same wiki.

``````procedure GetPath(i, j):
allPaths = empty 2d array
if next[i][j] is not empty:
for every k in next[i][j]:
if k == -1: // add the path = [i, j]
else: // add the path = [i .. k .. j]
paths_I_K = GetPath(i,k) // get all paths from i to k
paths_K_J = GetPath(k,j) // get all paths from k to j
for every path between i and k, i_k in paths_I_K:
for every path between k and j, k_j in paths_K_J:
i_k = i_k.popk() // remove the last element since that repeats in k_j
allPaths.add( array( i_k + j_k) )

return allPaths
``````

Note: `path[i][j]` is an adjacency list. While initializing `path[i][j]`, you can also initialize `next[i][j]` by adding a `-1` to the array. For instance an initialization of `next[i][j]` would be

``````for every edge (i,j) in graph:
next[i][j].push_back(-1)
``````

This takes care of an edge being the shortest path itself. You'll have to handle this special case in the path reconstruction, which is what i'm doing in `GetPath`.

-
I managed to make it work by adding `and k != j` to the `else if` statement. I then wrote a recursive function to step through `next`. It interprets a value in `next` which is equal to the current node as meaning that the next node can be accessed directly. Is this a reasonable way of interpreting/unravelling the next matrix? Or is there a cleaner/clearer way of doing it? –  user1507844 Jul 7 '12 at 14:32
@user1507844 Overlooked the `k != j` part. Edited my answer to reflect it. –  deebee Jul 7 '12 at 20:34
@user1507844 I added the code for path reconstruction. I've used `-1` as the index if there is a direct edge; but your technique of storing one of the nodes is also fine. –  deebee Jul 7 '12 at 21:03
I notice you also added `k != i`, what is that for? Not sure I understand the `-1` part. Where does an entry in `next` get set to `-1`? Is that what it is initialized to? Thanks again for the help –  user1507844 Jul 7 '12 at 23:50
@user1507844 Added notes for more clarification. –  deebee Jul 8 '12 at 1:06

The 'counting' function in the current approved answer flails in some cases. A more complete solution would be:

``````procedure FloydWarshallWithCount ()
for k := 1 to n
for i := 1 to n
for j := 1 to n
if path[i][j] == path[i][k]+path[k][j]
count[i][j] += count[i][k] * count[k][j]
else if path[i][j] > path[i][k] + path[k][j]
path[i][j] = path[i][k] + path[k][j]
count[i][j] = count[i][k] * count[k][j]
``````

The reason for this is that for any three vertices i, j, and k, there may be multiple shortest paths that run from i through k to j. For instance in the graph:

``````       3             1
(i) -------> (k) ---------> (j)
|            ^
|            |
| 1          | 1
|     1      |
(a) -------> (b)
``````

Where there are two paths from i to j through k. `count[i][k] * count[k][j]` finds the number of paths from i to k, and the number of paths from k to j, and multiplies them to find the number of paths i -> k -> j.

-