**UPDATE:** The OP now has had several rounds of clarifications, and it is a different problem now. I'll leave this here for documenting my ideas for the first version of the problem (or rather my understanding of it). I'll try a new answer for the current version of the problem.
**End of UPDATE**

It's a pity that the OP hasn't clarified some of the open questions. I'll assume the following:

- The weights are +/- 1.
- n is the number of vertices

The first assumption is no loss of generality, obviously, but it has great impact on the value of n (via the second assumption). Without the first assumption, even a tiny (fixed) graph can have arbitrary long solutions by varying the weights without limits.

The algorithm I propose is quite simple, and similar to well-known graph algorithms. I'm no graph expert though, so I may use the wrong words in some places. Feel free to correct me.

- For the source vertex, remember cost 0. Add (source, 0) to the todo list.
- Pop an item from the todo list. Follow all outgoing edges of the vertex, computing the new cost c to reach the new vertex v. If the new cost is valid (c >= 0
**and c <= n ^ 2**, see below) and not remembered for v, *add* it to the remembered cost values of v, and add (v, c) to your todo list.
- If the todo list is not empty, continue with step 2. (Or break early if the destination can be reached with cost 0).

It's clear that each "step" that's not an immediate dead end creates a new (vertex, cost) combination. There will be stored at most n * n ^2 = n ^ 3 of these combinations, and thus, in a certain sense, this algorithm is O(n^3).

**Now, why does this find the optimal path?** I don't have a real proof, but I think it the following ideas justify why I think this suffices, and it may be possible that they can be turned into a real proof.

I think it is clear that the only thing we have to show is that the condition c <= n ^ 2 is sufficient.

First, let's note that any (reachable) vertex can be reached with cost less than n.

Let (v, c) be part of an optimal path and c > n ^ 2.
As c > n, there must be some cycle on the path before reaching (v, c), where the cost of the cycle is 0 < m1 < n, and there must be some cycle on the path after reaching (v, c), where the cost of the cycle is 0 > m2 > -n.

Furthermore, let v be reachable from the source with cost 0 <= c1 < n, by a path that touches the first cycle mentioned above, and let the destination be reachable from v with cost 0 <= c2 < n, by a path that touches the other cycle mentioned above.

Then we can construct paths from source to v with costs c1, c1 + m1, c1 + 2 * m1, ..., and paths from v to destination with costs c2, c2 + m2, c2 + 2 * m2, ... . Choose 0 <= a <= m2 and 0 <= b <= m1 such that c1 + c2 + a * m1 + b * m2 is minimal and thus the cost of an optimal path. On this optimal path, v would have the cost c1 + a * m1 < n ^ 2.

If the gcd of m1 and m2 is 1, then the cost will be 0. If the gcd is > 1, then it might be possible to choose other cycles such that the gcd becomes 1. If that is not possible, it's also not possible for the optimal solution, and there will be a positive cost for the optimal solution.

(Yes, I can see several problems with this attempt of a proof. It might be necessary to take the gcd of several positive or negative cycle costs etc. I would be very interested in a counterexample, though.)

Here's some (Python) code:

```
def f(vertices, edges, source, dest):
# vertices: unique hashable objects
# edges: mapping (u, v) -> cost; u, v in vertices, cost in {-1, 1}
#vertex_costs stores the possible costs for each vertex
vertex_costs = dict((v, set()) for v in vertices)
vertex_costs[source].add(0) # source can be reached with cost 0
#vertex_costs_from stores for each the possible costs for each vertex the previous vertex
vertex_costs_from = dict()
# vertex_gotos is a convenience structure mapping a vertex to all ends of outgoing edges and their cost
vertex_gotos = dict((v, []) for v in vertices)
for (u, v), c in edges.items():
vertex_gotos[u].append((v, c))
max_c = len(vertices) ** 2 # the crucial number: maximal cost that's possible for an optimal path
todo = [(source, 0)] # which vertices to look at
while todo:
u, c0 = todo.pop(0)
for v, c1 in vertex_gotos[u]:
c = c0 + c1
if 0 <= c <= max_c and c not in vertex_costs[v]:
vertex_costs[v].add(c)
vertex_costs_from[v, c] = u
todo.append((v, c))
if not vertex_costs[dest]: # destination not reachable
return None # or raise some Exception
cost = min(vertex_costs[dest])
path = [(dest, cost)] # build in reverse order
v, c = dest, cost
while (v, c) != (source, 0):
u = vertex_costs_from[v, c]
c -= edges[u, v]
v = u
path.append((v, c))
return path[::-1] # return the reversed path
```

And the output for some graphs (edges and their weight / path / cost at each point of the path; sorry, no nice images):

```
AB+ BC+ CD+ DA+ AX+ XY+ YH+ HI- IJ- JK- KL- LM- MH-
A B C D A X Y H I J K L M H
0 1 2 3 4 5 6 7 6 5 4 3 2 1
AB+ BC+ CD+ DE+ EF+ FG+ GA+ AX+ XY+ YH+ HI- IJ- JK- KL- LM- MH-
A B C D E F G A B C D E F G A B C D E F G A X Y H I J K L M H I J K L M H I J K L M H I J K L M H
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
AB+ BC+ CD+ DE+ EF+ FG+ GA+ AX+ XY+ YH+ HI- IJ- JK- KL- LM- MN- NH-
A X Y H
0 1 2 3
AB+ BC+ CD+ DE+ EF+ FG+ GA+ AX+ XY+ YH+ HI- IJ- JK- KL- LM- MN- NO- OP- PH-
A B C D E F G A B C D E F G A B C D E F G A B C D E F G A B C D E F G A B C D E F G A X Y H I J K L M N O P H I J K L M N O P H I J K L M N O P H I J K L M N O P H I J K L M N O P H
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
```

Here's the code to produce that output:

```
def find_path(edges, source, path):
from itertools import chain
print(edges)
edges = dict(((u, v), 1 if c == "+" else -1) for u, v, c in edges.split())
vertices = set(chain(*edges))
path = f(vertices, edges, source, dest)
path_v, path_c = zip(*path)
print(" ".join("%2s" % v for v in path_v))
print(" ".join("%2d" % c for c in path_c))
source, dest = "AH"
edges = "AB+ BC+ CD+ DA+ AX+ XY+ YH+ HI- IJ- JK- KL- LM- MH-"
# uv+ means edge from u to v exists and has cost 1, uv- = cost -1
find_path(edges, source, path)
edges = "AB+ BC+ CD+ DE+ EF+ FG+ GA+ AX+ XY+ YH+ HI- IJ- JK- KL- LM- MH-"
find_path(edges, source, path)
edges = "AB+ BC+ CD+ DE+ EF+ FG+ GA+ AX+ XY+ YH+ HI- IJ- JK- KL- LM- MN- NH-"
find_path(edges, source, path)
edges = "AB+ BC+ CD+ DE+ EF+ FG+ GA+ AX+ XY+ YH+ HI- IJ- JK- KL- LM- MN- NO- OP- PH-"
find_path(edges, source, path)
```

lengthof the path, or the path itself? If you want the path itself, you can't get an efficient algorithm in all cases, since the length of this path might be exponentially long (think about a hugely negative edge with a long cycle before it; you have to go around the cycle a lot before you can cross the edge.)8more comments