I have made a few attempts at trying to create a polynomial graph isomorphism algorithm, and while I have yet to create an algorithm that is proven to be polynomial for every case, one algorithm I came up with is particularly suited for this purpose. It's based on a DFA minimization algorithm (the specific algorithm is http://en.wikipedia.org/wiki/DFA_minimization#Hopcroft.27s_algorithm ; you may want to find a description from elsewhere, since Wikipedia's is difficult to follow).
The original algorithm was initialized by organizing the vertexes into distinct groups based on degree (one group for vertexes of degree 1, one for vertexes of degree 2, etc.). For your purposes, you will want to organize the vertexes into groups based upon both degree and label; this will ensure that no two nodes will be paired if they have different labels. Each graph should have its own structure containing such groups. Check the collection of groups for both graphs; there should be the same number of groups for the two graphs, and for each group in one graph, there should be a group in the other graph containing the same number of vertexes of the same degree and label. If this isn't the case, the graphs aren't isomorphic.
At each iteration of the main algorithm, you should generate a new data structure for each of the two graphs for the vertex groups that the next step will use. For each group, generate a list for each vertex of group indices/IDs that correspond to the vertexes that are adjacent to the vertex in question (include duplicate groups in this list). Check each group to see if the sorted group index/ID list for each contained vertex is the same. If this is the case, create a unmodified copy of this group in the next step's group structure. If this isn't the case, then for each unique list of group indices/IDs within that group, create a new group for vertexes within the original group that generated that list and add this new group to the next step's group structure. If you do not subdivide any of the groups of either graph in a given iteration, stop running the main portion of this algorithm. If you subdivide at least one group, you will need to once again check to make sure the group structures of the two graphs correspond to each other. This check will be similar to the one performed at the end of the algorithm's initialization (you may even be able to use the same function for both). If this check fails, then the graphs aren't isomorphic. If the check passes, then discard/free the current group structures and start the next iteration with the freshly created ones.
To make the process of determining "corresponding groups" easier, I would highly recommend using a predictable scheme for adding groups to the structure. For example, if you add groups during initialization in (degree, label) order, subdivide groups in ascending index order, and add subdivided groups to the new structure based on the order of the group index list (i.e., sorted by first listed index, then second, etc.), then corresponding groups between the two group structures will always have the same index, which makes the process of keeping track of which groups correspond to each other much easier.
If all groups contain 3 or fewer vertexes when the algorithm completes, then the graphs are isomorphic (for corresponding groups containing 2 or 3 vertexes, any vertex pairing is valid). If this isn't the case (this always happens for graphs where all nodes have equal degree and label, and sometimes happens for subgraphs with that property), then the graphs are not yet determined to be isomorphic or non-isomorphic. To differentiate between the two cases, choose an arbitrary node of the first graph's largest group and separate it into its own group. Then, for each node of the other graph's largest group, try running the algorithm again with that node separated into its own group. In essence, you are choosing an unpaired node from the first graph and pairing it by guess-and-check to every node in the second graph that is still a plausible pairing. If any of the forked iterations returns an isomorphism, the graphs are isomorphic. If none of them do, the graphs are not isomorphic.
For general cases, this algorithm is polynomial. In corner cases, the algorithm might be exponential. Whether this is the case or not is related to how frequently the algorithm can be forced to fork in the worst case of both graph input and node selection, which I have had difficulties trying to put useful bounds on. For example, although the algorithm forks at every step when comparing two full graphs, every branch of that tree produces an isomorphism; therefore, the algorithm returns in polynomial time in this case even though traversing the entire execution tree would require exponential time since traversing only one branch of the execution tree takes polynomial time.
Regardless, this algorithm should work well for your purposes. I hope my explanation of it was comprehensible; if not, I can try providing examples of the algorithm handling simple cases or expressing it as pseudocode instead.