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]
allPaths.add( array[ 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`

.

`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