First, i would strongly recommend the book *Social Network Analysis for Startups* by Maksim Tsvetovat and Alexander Kouznetsov. A book like this is a godsend for programmers who need to quickly acquire a basic fluency in a specific discipline (in this case, graph theory) so that they can begin writing code to solve problems in this domain. Both authors are academically trained graph theoreticians but the intended audience of their book is programmers. Nearly all of the numerous examples presented in the book are in python using the networkx library.

Second, for the projects you have in mind, *two* kinds of libraries are very helpful if not indispensible:

**graph analysis**: e.g., the excellent **networkx** (python), or **igraph**
(python, R, *et. al*.) are two that i can recommend highly; and

**graph rendering**: the excellent **graphViz**, which can be used
stand-alone from the command line but more likely you will want to
use it as a library; there are graphViz bindings in all major
languages (e.g., for python there are at least three i know of,
though pygraphviz is my preference; for R there is rgraphviz which is
part of the bioconductor package suite). Rgraphviz has excellent documentation (see in particular the Vignette included with the Package).

It is very easy to install and begin experimenting with these libraries and in particular using them

to learn the essential graph theoretic lexicon and units of analysis
(e.g., degree sequence distribution, nodes traversal, graph
operators);

to distinguish critical nodes in a graph (e.g., degree centrality,
eigenvector centrality, assortivity); and

to identify prototype graph substructures (e.g., bipartite structure,
triangles, cycles, cliques, clusters, communities, and cores).

The value of using a graph-analysis library to quickly understand these essential elements of graph theory is that for the most part there is a **1:1 mapping** between the *concepts* i just mentioned and *functions* in the (networkx or igraph) library.

So e.g., you can quickly generate two random graphs of equal size (node number), render and then view them, then easily calculate for instance the average degree sequence or betweenness centrality for both and observer first-hand how changes in the value of those parameters affects the structure of a graph.

W/r/t the combination of ML and Graph Theoretic techniques, here's my limited personal experience. I use ML in my day-to-day work and graph theory less often, but rarely together. This is just an empirical observation limited to my personal experience, so the fact that i haven't found a problem in which it has seemed natural to combine techniques in these two domains. Most often graph theoretic analysis is useful in ML's *blind spot*, which is the *availability of a substantial amount of labeled training data*--supervised ML techniques depend heavily on this.

One class of problems to illustrate this point is *online fraud detection/prediction*. It's almost never possible to gather data (e.g., sets of online transactions attributed to a particular user) that you can with reasonable certainty separate and label as "fraudulent account." If they were particularly clever and effective then you will mislabel as "legitimate" and for those accounts for which fraud was suspected, quite often the first-level diagnostics (e.g., additional id verification or an increased waiting period to cash-out) are often enough to cause them to cease further activity (which would allow for a definite classification). Finally, even if you somehow manage to gather a reasonably noise-free data set for training your ML algorithm, it will certainly be seriously unbalanced (i.e., much more "legitimate" than "fraud" data points); this problem can be managed with statistics pre-processing (resampling) and by algorithm tuning (weighting) but it's still a problem that will likely degrade the quality of your results.

So while i have never been able to successfully use ML techniques for these types of problems, in at least two instances, i have used graph theory with some success--in the most recent instance, by applying a model adapted from the project by a group at Carnegie Mellon initially directed to detection of online auction fraud on ebay.