I want to be able to generate random, undirected, and connected graphs in Java. In addition, I want to be able to control the maximum number of vertices in the graph. I am n
The only tricky part is ensuring that the final graph is connected. To do that, you can use a disjoint set data structure. Keep track of the number of components, initially n. Repeatedly pick pairs of random vertices u and v, adding the edge (u, v) to the graph and to the disjoint set structure, and decrementing the component count when the that structure tells you u and v belonged to different components. Stop when the component count reaches 1. (Note that using an adjacency matrix simplifies managing the case where the edge (u, v) is already present in the graph: in this case, adj[u][v] will be set to 1 a second time, which as desired has no effect.)
If you find this creates graphs that are too dense (or too sparse), then you can use another random number to add edges only k% of the time when the endpoints are already part of the same component (or when they are part of different components), for some k.
The following paper proposes an algorithm that uniformly samples connected random graphs with prescribed degree sequence, with an efficient implementation. It is available in several libraries, like Networkit or igraph.
Fast generation of random connected graphs with prescribed degrees. Fabien Viger, Matthieu Latapy
Be careful when you make simulations on random graphs: if they are not sampled uniformly, then they may have hidden properties that impact simulations; alternatively, uniformly sampled graphs may be very different from the ones your code will meet in practice...
Whatever you want to do with your graph, I guess its density is also an important parameter. Otherwise, you'd just generate a set of small cliques (complete graphs) using random sizes, and then connect them randomly.
If I'm correct, I'd advise you to use the Erdős-Rényi model: it's simple, not far from what you originally proposed, and allows you to control the graph density (so, basically: the number of links).
Here's a short description of this model:
With this model, if your p is large enough, then it's highly probable your graph is connected (cf. the Wikipedia reference for details). In any case, if you have several components, you can also force its connectedness by creating links between nodes of distinct components. First, you have to identify each component by performing breadth-first searches (one for each component). Then, you select pairs of nodes in two distinct components, create a link between them and consider both components as merged. You repeat this process until you've got a single component remaining.