# Find all possible paths in a directed cyclic graph

I want to find all possible paths in a directed cyclic graph. I have written a program which does so, but I notice that if the number of nodes grow above 40 or 50, it starts taking infinite time.

Theoretically speaking how many paths are possible for a directed cyclic graph of N nodes. Is it like factorial(N) or something? Can you give me a guess for the following example with 119 nodes. Of course, I am going over loops only once, so you can ignore the cyclic paths.

Graph Image

-
Holy shit...... On another note: What have you tried? On a third note: Pick c or c++, not both. –  Drise Aug 30 '12 at 16:01
I have tried Depth First search. –  user1018562 Aug 30 '12 at 16:03
At this moment I am interested in knowing the theoretical limit. –  user1018562 Aug 30 '12 at 16:06
Theoretical limit is based on the computer, architecture, and I could go on. Even up to compiler flags used. You need to analyze your algorithm in great detail. Start with small cases. –  Drise Aug 30 '12 at 16:07

Let's just take this common pattern that shows in your graph:

``````A ---> B
|     /|
|    / v
|   /  C
|  /   |
| /    |
vv    /
D <---
``````

Excuse the ASCII art. So you have three paths here: `A -> D`, `A -> B -> D`, and `A -> B -> C -> D`.

Now say you have the exact same figure emanating from `D` to another node `G`:

``````D ---> E
|     /|
|    / v
|   /  F
|  /   |
| /    |
vv    /
G <---
``````

You have the same analogous three paths as before: `D -> G`, `D -> E -> G`, and `D -> E -> F -> G`.

Now, how many paths are there from `A` to `G`?

To get from `A` to `G`, you have to get from `A` to `D`. You can do this in one of three ways. Then you have to get from `D` to `G`. You can do this in one of three ways. These two choices (`A` to `D` and `D` to `G`) are independent of each other. Thus you have `3` * `3` = `9` possible paths from `A` to `G`.

If you keep repeating the figure, you multiply the number of possible paths by `3` with each repetition. So with three figures, 27 paths; with four figures, 81 paths; etc.

That's exponential growth. Put differently: you'll have to find another way to do what it is you're doing, if you want to be efficient about it.

EDIT: To get a rough estimate: only counting those figures, not even looking at the complex jumbles in the middle, I get `3 * 3 * 3 * 3 * (2^8) * (4^8) * 3 * 3 * 2 * 3` = `73383542784` possible paths, through just those simple nodes.

EDIT: You seem to be doing code analysis. Without knowing exactly what you want to do, what I recommend is consolidating whatever information you're gathering along those nodes that must be reached (e.g. nodes `A`, `D`, and `G` in my example figures). Then do a search until you get to the next node that must be reached, and gather your info there as well. This will prevent exponential blow-up.

-
So it looks like he's in the O(n^2) or O(n^3) range? –  Drise Aug 30 '12 at 16:09
No, O(2^n) or O(3^n) –  Claudiu Aug 30 '12 at 16:10
More like b^n, where b is the branching factor, or the number of outgoing edges from a node. –  beaker Aug 30 '12 at 16:11
Oh.. Right. Had my exponents/bases switched. –  Drise Aug 30 '12 at 16:12
73383542784 for how many nodes you mean? –  user1018562 Aug 30 '12 at 16:13