Since the existing non-recursive DFS implementation given in this answer seems to be broken, let me provide one that actually works.

I've written this in Python, because I find it pretty readable and uncluttered by implementation details (and because it has the handy `yield`

keyword for implementing generators), but it should be fairly easy to port to other languages.

```
# a generator function to find all simple paths between two nodes in a
# graph, represented as a dictionary that maps nodes to their neighbors
def find_simple_paths(graph, start, end):
visited = set()
visited.add(start)
nodestack = list()
indexstack = list()
current = start
i = 0
while True:
# get a list of the neighbors of the current node
neighbors = graph[current]
# find the next unvisited neighbor of this node, if any
while i < len(neighbors) and neighbors[i] in visited: i += 1
if i >= len(neighbors):
# we've reached the last neighbor of this node, backtrack
visited.remove(current)
if len(nodestack) < 1: break # can't backtrack, stop!
current = nodestack.pop()
i = indexstack.pop()
elif neighbors[i] == end:
# yay, we found the target node! let the caller process the path
yield nodestack + [current, end]
i += 1
else:
# push current node and index onto stacks, switch to neighbor
nodestack.append(current)
indexstack.append(i+1)
visited.add(neighbors[i])
current = neighbors[i]
i = 0
```

This code maintains two parallel stacks: one containing the earlier nodes in the current path, and one containing the current neighbor index for each node in the node stack (so that we can resume iterating through the neighbors of a node when we pop it back off the stack). I could've equally well used a single stack of (node, index) pairs, but I figured the two-stack method would be more readable, and perhaps easier to implement for users of other languages.

This code also uses a separate `visited`

set, which always contains the current node and any nodes on the stack, to let me efficiently check whether a node is already part of the current path. If your language happens to have an "ordered set" data structure that provides both efficient stack-like push/pop operations *and* efficient membership queries, you can use that for the node stack and get rid of the separate `visited`

set.

Alternatively, if you're using a custom mutable class / structure for your nodes, you can just store a boolean flag in each node to indicate whether it has been visited as part of the current search path. Of course, this method won't let you run two searches on the same graph in parallel, should you for some reason wish to do that.

Here's some test code demonstrating how the function given above works:

```
# test graph:
# ,---B---.
# A | D
# `---C---'
graph = {
"A": ("B", "C"),
"B": ("A", "C", "D"),
"C": ("A", "B", "D"),
"D": ("B", "C"),
}
# find paths from A to D
for path in find_simple_paths(graph, "A", "D"): print " -> ".join(path)
```

Running this code on the given example graph produces the following output:

A -> B -> C -> D
A -> B -> D
A -> C -> B -> D
A -> C -> D

Note that, while this example graph is undirected (i.e. all its edges go both ways), the algorithm also works for arbitrary directed graphs. For example, removing the `C -> B`

edge (by removing `B`

from the neighbor list of `C`

) yields the same output except for the third path (`A -> C -> B -> D`

), which is no longer possible.

**Ps.** It's easy to construct graphs for which simple search algorithms like this one (and the others given in this thread) perform very poorly.

For example, consider the task of find all paths from A to B on an undirected graph where the starting node A has two neighbors: the target node B (which has no other neighbors than A) and a node C that is part of a clique of *n*+1 nodes, like this:

```
graph = {
"A": ("B", "C"),
"B": ("A"),
"C": ("A", "D", "E", "F", "G", "H", "I", "J", "K", "L", "M", "N", "O"),
"D": ("C", "E", "F", "G", "H", "I", "J", "K", "L", "M", "N", "O"),
"E": ("C", "D", "F", "G", "H", "I", "J", "K", "L", "M", "N", "O"),
"F": ("C", "D", "E", "G", "H", "I", "J", "K", "L", "M", "N", "O"),
"G": ("C", "D", "E", "F", "H", "I", "J", "K", "L", "M", "N", "O"),
"H": ("C", "D", "E", "F", "G", "I", "J", "K", "L", "M", "N", "O"),
"I": ("C", "D", "E", "F", "G", "H", "J", "K", "L", "M", "N", "O"),
"J": ("C", "D", "E", "F", "G", "H", "I", "K", "L", "M", "N", "O"),
"K": ("C", "D", "E", "F", "G", "H", "I", "J", "L", "M", "N", "O"),
"L": ("C", "D", "E", "F", "G", "H", "I", "J", "K", "M", "N", "O"),
"M": ("C", "D", "E", "F", "G", "H", "I", "J", "K", "L", "N", "O"),
"N": ("C", "D", "E", "F", "G", "H", "I", "J", "K", "L", "M", "O"),
"O": ("C", "D", "E", "F", "G", "H", "I", "J", "K", "L", "M", "N"),
}
```

It's easy to see that the only path between A and B is the direct one, but a naïve DFS started from node A will waste O(*n*!) time uselessly exploring paths within the clique, even though it's obvious (to a human) that none of those paths can possibly lead to B.

One can also construct DAGs with similar properties, e.g. by having the starting node A connect target node B and to two other nodes C_{1} and C_{2}, both of which connect to the nodes D_{1} and D_{2}, both of which connect to E_{1} and E_{2}, and so on. For *n* layers of nodes arranged like this, a naïve search for all paths from A to B will end up wasting O(2^{n}) time examining all the possible dead ends before giving up.

Of course, adding an edge to the target node B from one of the nodes in the clique (other than C), or from the last layer of the DAG, *would* create an exponentially large number of possible paths from A to B, and a purely local search algorithm can't really tell in advance whether it will find such an edge or not. Thus, in a sense, the poor output sensitivity of such naïve searches is due to their lack of awareness of the global structure of the graph.

While there are various preprocessing methods (such as iteratively eliminating leaf nodes, searching for single-node vertex separators, etc.) that could be used to avoid some of these "exponential-time dead ends", I don't know of any general preprocessing trick that could eliminate them in *all* cases. A general solution would be to check at every step of the search whether the target node is still reachable (using a sub-search), and backtrack early if it isn't — but alas, that would significantly slow down the search (at worst, proportionally to the size of the graph) for many graphs that *don't* contain such pathological dead ends.