It's no doubt that there would be a huge amount of shortest paths in the graph. So it is hard to generate all shortest path in a satisfied time-complexity. But I can give you a simple method that can get as much shortest paths as you want.

## Algorithm

- Run Dijkstra algorithm from starting point, and get disS[i] list(the shortest distance
between starting point and point i). And then run Dijkstra algorithm from ending point, and get disT[i] list(the shortest distance between ending point and point i)
- Make a new graph: for a edge in the original graph, if
disS[a] + disT[b] + w(a, b) == disS[ending point], we add a edge in new graph. It's obviously that the new graph is a DAG(Directed acyclic graph), and has a sink(starting point) and a target(ending point). Any path from sink to the target would be a shortest path in the original graph.
- You can run DFS in the new graph. Save the path information in the
recursion and backtracking, any time you reach the target, the saved
information would be one shortest path. When the algorithm ending is all depend on you.

## Pseudo Code：

```
def find_one_shortest_path(graph, now, target, path_info):
if now == target:
print path_info
return
for each neighbor_point of graph[now]:
path_info.append(neighbor_point)
find_one_shortest_path(graph, neighbor_point, target, path_info) #recursion
path_info.pop(-1) #backtracking
def all_shortest_paths(graph, starting_point, ending_point):
disS = [] # shortest path from S
disT = [] # shortest path from T
new_graph = []
disS = Dijkstra(graph, starting_point)
disT = Dijkstra(graph, endinng_point)
for each edge<a, b> in graph:
if disS[a] + w<a, b> + disT[b] == disS[ending_point]:
new_graph.add(<a, b>)
find_one_shortest_path(new_graph, starting_point, ending_point, [])
```