# Generating a random cubic graph with uniform probability (or less)

While this may look like homework, I assure you it's not. It stems from some homework assignment I did, though.

Let's call an undirected graph without self-edges "cubic" if every vertex has degree exactly three. Given a positive integer N I'd like to generate a random cubic graph on N vertices. I'd like for it to have uniform probability, that is, if there are M cubic graphs on N vertices the probability of generating each one is 1/M. A weaker condition that is still fine is that every cubic graph has non-zero probability.

I feel there's a quick and smart way to do this, but so far I've been unsuccessful.

PRE: edges = (3*nodes)/2, nodes is even, the constants are selected in such a way that the hash works (BIG_PRIME is bigger than edges, SMALL_PRIME is bigger than nodes, LOAD_FACTOR is small).

``````void random_cubic_graph() {

int i, j, k, count;
int *degree;
char guard;

count = 0;
degree = (int*) calloc(nodes, sizeof(int));

while (count < edges) {

/* Try a new edge at random */

guard = 0;
i = rand() % nodes;
j = rand() % nodes;

/* Checks if it is a self-edge */

if (i == j)
guard = 1;

/* Checks that the degrees are 3 or less */

if (degree[i] > 2 || degree[j] > 2)
guard = 1;

/* Checks that the edge was not already selected with an hash */

k = 0;
while(A[(j + k*BIG_PRIME) % (LOAD_FACTOR*edges)] != 0) {
if (A[(j + k*BIG_PRIME) % (LOAD_FACTOR*edges)] % SMALL_PRIME == j)
if ((A[(j + k*BIG_PRIME) % (LOAD_FACTOR*edges)] - j) / SMALL_PRIME == i)
guard = 1;
k++;
}

if (guard == 0)
A[(j + k*BIG_PRIME) % (LOAD_FACTOR*edges)] = hash(i,j);

k = 0;
while(A[(i + k*BIG_PRIME) % (LOAD_FACTOR*edges)] != 0) {
if (A[(i + k*BIG_PRIME) % (LOAD_FACTOR*edges)] % SMALL_PRIME == i)
if ((A[(i + k*BIG_PRIME) % (LOAD_FACTOR*edges)] - i) / SMALL_PRIME == j)
guard = 1;
k++;
}

if (guard == 0)
A[(i + k*BIG_PRIME) % (LOAD_FACTOR*edges)] = hash(j,i);

/* If all checks were passed, increment the count, print the edge, increment the degrees. */

if (guard == 0) {
count++;
printf("%d\t%d\n", i, j);
degree[i]++;
degree[j]++;
}

}
``````

The problem is that its final edge that has to be selected might be a self-edge. That happens when N - 1 vertices have already degree 3, only 1 has degree 1. Thus the algorithm might not terminate. Moreover, I'm not entirely convinced that the probability is uniform.

There's probably much to improve in my code, but can you suggest a better algorithm to implement?

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I suggest not using C language for graph algorithms when you are just a beginner. –  Hamish Grubijan Jun 24 '10 at 18:26
So, are your representing your graph as a square matrix? By the way, what is this small_prime, big_prime, and load_factor business? Sounds to me like you copied somebody else's solution and are trying to make sense of it. –  Hamish Grubijan Jun 24 '10 at 18:49
There's no square matrix: A is a vector of length LOAD_FACTOR*edges that contains the edges. Let's just pretend that there's a blackbox function is_edge_present(int i, int j) that checks if the (i, j) edge was already selected. That snippet of code does that, and if the edge was not selected it selects it for future searches. Isn't it a bit rude to assume that I copied? I wrote that. It's convoluted and messy, but that's why there's a beginner tag. –  Jacopo Notarstefano Jun 24 '10 at 19:08

Assume N is even. (Otherwise there cannot be a cubic graph on N vertices).

You can do the following:

Take 3N points and divide them into N groups of 3 points each.

Now pair up these 3N points randomly (note: 3N is even). i.e. Marry two points off randomly and form 3N/2 marriages).

If there is a pairing between group i and group j, create an edge between i and j. This gives a graph on N vertices.

If this random pairing does not create any multiple edges or loops, you have a cubic graph.

If not try again. This runs in expected linear time and generates a uniform distribution.

Note: all cubic graphs on N vertices are generated by this method (responding to Hamish's comments).

To see this:

Let G be a cubic graph on N vertices.

Let the vertices be, 1, 2, ...N.

Let the three neighbours of j be A(j), B(j) and C(j).

For each j, construct the group of ordered pairs { (j, A(j)), (j, B(j)), (j, C(j)) }.

This gives us 3N ordered pairs. We pair them up: (u,v) is paired with (v,u).

Thus any cubic graph corresponds to a pairing and vice versa...

More information on this algorithm and faster algorithms can be found here: Generating Random Regular Graphs Quickly.

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What if this misses some "cubic graphs"? What if some MUST be generated using some other method? –  Hamish Grubijan Jun 24 '10 at 18:53
Thank you, I think this settles my question. I'll wait just a few more hours before accepting your answer in case there's an even better solution coming up! –  Jacopo Notarstefano Jun 24 '10 at 19:19
@Hamish: See my edit. All cubic graphs are generated... –  Aryabhatta Jun 24 '10 at 19:23
When you say "no loops," you just mean from one grouping to another and back, right? –  BlueRaja - Danny Pflughoeft Jun 24 '10 at 23:40
@BlueRaja: No, a loop means a pairing of points in the same group. Going to a different group and coming back immediately is a multiple edge :-) –  Aryabhatta Jun 25 '10 at 0:31

Warning: I make a lot of intuitive-but-maybe-wrong claims in this answer. You should definitely prove them if you intend to use this idea.

Enumerating Cubic Graphs

When dealing with a random choice, a good starting point is to figure out how to enumerate over all of your possible elements. This might reveal some of the structure, and lead you to an algorithm.

Here is my strategy for enumerating cubic graphs: pick the first vertex, and iterate over all possible choices of three adjacent vertices. During those iterations, recurse on the next vertex, with the caveat that you keep track of how many edges are needed for each vertex degree to reach 3. Continue in that fashion until the lowest level is reached. Now you have your first cubic graph. Undo the recently added edges and continue to the next possibility until there are none left. There are a few implementation details you need to consider, but generally straight-forward.

Generalize Enumeration into Choice

Once you can enumerate all the elements, it is trivial to make a random choice. For example, you can scan the list once to compute its size then pick a random number in [0, size) then scan the sequence again to get the element at that offset. This is incredibly inefficient, taking at LEAST time proportional to the O(n^3) number of cubic graphs, but it works.

Sacrifice Uniform Probability for Efficiency

The obvious speed-up here is to make random edge choices at each level, instead of iterating over each possibility. Unfortunately, this will favor some graphs because of how your early choices affect the availability of later choices. Taking into account the need to track the remaining free vertices, you should be able to achieve O(n log n) time and O(n) space. Significantly better than the enumerating algorithm.

...

It's probably possible to do better. Probably a lot better. But this should get you started.

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This is an interesting general strategy that I overlooked. I might want to resort to this strategy next time. Thank you! –  Jacopo Notarstefano Jun 25 '10 at 0:31
Note that you can pick an element uniformly at random from a list by scanning it just one time, no need to compute the size first: en.wikipedia.org/wiki/Reservoir_sampling (let k = 1) –  Paulpro Nov 27 '13 at 20:04