I'm working on better understanding the application of a depth-first search algorithm. I understand how to use it to traverse a binary search tree to produce a sorted list. My Python implementation looks like this:

```
class bst_node:
def __init__(self, x):
self.x = x
self.left = None
self.right = None
def get_dfs_path(bst_node):
""" Returns a depth-first search path for a BST """
left = [] if bst_node.left == None else get_dfs_path(bst_node.left)
right = [] if bst_node.right == None else get_dfs_path(bst_node.right)
return left + [bst_node] + right
```

Which works quite nicely. I'm struggling to understand, however, whether this algorithm can be meaningfully applied to a digraph in general, rather than the more strict BST. Consider the following digraph node implementation:

```
class di_node:
def __init__(self, x):
self.x = x
self.visited = False
self.children = []
```

Since a node in a digraph can have an arbitrary number of children, the dfs logic can't simply construct the path as `dfs_path(left) + parent_node + dfs_path(right)`

. Can someone help me understand if/how dfs applies to a digraph?

EDIT

Ok, based on the responses let me attempt a dfs traversal for a di_node. Please let me know if I'm anywhere close to the mark:

```
def get_dfs_path(di_node):
""" Returns a depth-first search path for a digraph """
if di_node.visited:
return []
else:
di_node.visited = True
return [di_node] + [ get_dfs_path(child) for child in di_node.children) ]
```