Wikipedia actually has some pretty good pseudocode for depth-first traversal. These traversal algorithms label all the nodes in the graph with the order they appear in a traversal. You instead want to immediately return the path to the goal when the goal is found.

So let's modify the Wikipedia algorithm:

```
( INCORRECT ALGORITHM DELETED WHICH THE OP COMMENTED ON CORRECTLY BELOW )
```

Here is a Python implementation:

```
g = {
'A': ['B', 'C', 'D'],
'B': ['C', 'E', 'F'],
'C': ['A'],
'D': ['B', 'F', 'G', 'H'],
'E': ['G'],
'F': ['A', 'F'],
'G': ['H', 'I'],
'H': [],
'I': []
}
def DFS(g, v, goal, explored, path_so_far):
""" Returns path from v to goal in g as a string (Hack) """
explored.add(v)
if v == goal: return path_so_far + v
for w in g[v]:
if w not in explored:
p = DFS(g, w, goal, explored, path_so_far + v)
if p: return p
return ""
# Hack unit test
print(DFS(g, 'A', 'I', set([]), "") == "ABEGI")
print(DFS(g, 'A', 'E', set([]), "") == "ABE")
print(DFS(g, 'B', 'B', set([]), "") == "B")
print(DFS(g, 'B', 'B', set([]), "") == "B")
print(DFS(g, 'A', 'M', set([]), "") == "")
print(DFS(g, 'B', 'A', set([]), "") == "BCA")
print(DFS(g, 'E', 'A', set([]), "") == "")
```

The idea here is that you want to find, in graph `g`

, the path from `v`

to `goal`

, given that you already have come along the path in `path_so_far`

. `path_so_far`

should actually end just before `v`

.

If `v`

is the goal, you can add `v`

to path so far and that's it.

Otherwise, you will need to explore all edges emminating from `v`

that do not have already explored nodes on the other end of the edge. For each of these edges you can search (recursively) using your path so far plus the current node. If there is no path to the goal from `v`

you will return an empty path.

The nice thing is that you are using recursion to "automatically backtrack" because you are passing the augmented path into your recursive call.