Dijkstra's Algorithm (here, in Python) works great:

```
def find_all_paths(graph, start, end, path=[]):
path = path + [start]
if start == end:
return [path]
if start not in graph:
return []
paths = []
for node in graph[start]:
if node not in path:
newpaths = find_all_paths(graph, node, end, path)
for newpath in newpaths:
paths.append(newpath)
return paths
def min_path(graph, start, end):
paths=find_all_paths(graph,start,end)
mt=10**99
mpath=[]
print '\tAll paths:',paths
for path in paths:
t=sum(graph[i][j] for i,j in zip(path,path[1::]))
print '\t\tevaluating:',path, t
if t<mt:
mt=t
mpath=path
e1=' '.join('{}->{}:{}'.format(i,j,graph[i][j]) for i,j in zip(mpath,mpath[1::]))
e2=str(sum(graph[i][j] for i,j in zip(mpath,mpath[1::])))
print 'Best path: '+e1+' Total: '+e2+'\n'
if __name__ == "__main__":
graph = {'D1': {'D2':1, 'C1':1},
'D2': {'C2':1, 'D1':1},
'C1': {'C2':1, 'B1':1, 'D1':1},
'C2': {'D2':1, 'C1':1, 'B2':1},
'B1': {'C1':1, 'B2':1},
'B2': {'B1':1, 'A2':1, 'C2':1},
'A2': {'B2':1, 'A1':1},
'A1': {'A2':1}}
min_path(graph,'D1','A1')
```

Prints:

```
All paths: [['D1', 'C1', 'C2', 'B2', 'A2', 'A1'], ['D1', 'C1', 'B1', 'B2', 'A2', 'A1'], ['D1', 'D2', 'C2', 'C1', 'B1', 'B2', 'A2', 'A1'], ['D1', 'D2', 'C2', 'B2', 'A2', 'A1']]
evaluating: ['D1', 'C1', 'C2', 'B2', 'A2', 'A1'] 5
evaluating: ['D1', 'C1', 'B1', 'B2', 'A2', 'A1'] 5
evaluating: ['D1', 'D2', 'C2', 'C1', 'B1', 'B2', 'A2', 'A1'] 7
evaluating: ['D1', 'D2', 'C2', 'B2', 'A2', 'A1'] 5
Best path: D1->C1:1 C1->C2:1 C2->B2:1 B2->A2:1 A2->A1:1 Total: 5
```

If you change the number in the dict (in this case, all `1`

for same cost) that will change the 'cost' of using that segment of the path. There is an example using train routes.