threading=multi doesn't mean that things like boost containers will suddenly become safe for concurrent access by multiple threads (that would be prohibitively expensive from a performance point of view).
Rather, what it means in theory is that boost will be compiled to be thread aware. Basically this means that boost methods and classes will behave in a reasonable default way when accessed from multiple threads, much like classes in the std library. This means that you cannot access the same object from multiple threads, unless otherwise documented, but you can access different objects from multiple threads, safely. This might seem obvious, even without explicit support, but any
static state used by the library would break that guarantee if not protected. Using
threading=multi guarantees that any such shared state is property guarded by mutex or some other mechanism.
In the past similar arguments or stdlib flavors were available for the C and C++ std libraries supplied my compilers, although today mostly just the multithreaded versions are available.
There is likely little downside to compiling with
threading=multi, given that only a limited amount of static state need to be synchronized. Your comment that your library will mostly only be called by a single thread doesn't inspire a lot of confidence - after all, those are the kinds of latent bugs that will cause you to be woken up at 3 AM by your boss after a night of long drinking.
The example of boost's
shared_ptr is informative. With
threading=single, it is not even guaranteed that independent manipulation of two
shared_ptr instances, from multiple threads, is safe. If they happen to point to the same object (or, in theory, under some exotic implementations even if they don't), you will gen undefined behavior, because shared state won't be manipulated with the proper protections.
threading=multi, this won't happen. However, it is still not safe to access the same
shared_ptr instance from multiple threads. That is, it doesn't give any thread safety guarantees which aren't documented for the object in question - but it does give the "expected/reasonable/default" guarantees of independent objects being independent. There isn't a good name for this default level of thread-safety, but it is in fact what's generally offered all standard libraries for multi-threaded languages today.
As a final point, it's worth noting that
Boost.Thread is implicitly always compiled with
threading=multi - since using boost's multithreaded classes is an implicit hint that multiple threads are present. Using
Boost.Thread without multithreaded support would be nonsensical.
Now, all that said, the above is the theoretical idea behind compiling boost "with thread support" or "without thread support" which is the purpose of the
threading= flag. In practice, since this flag was introduced, multithreading has become the default, and single threading the exception. Indeed, many compilers and linkers which defaulted to single threaded behavior, now default to multithreaded - or at least require only a single "hint" (e.g., the presence of -pthread on the command line) to flip to multithreaded.
Apart from that, there has also been a concerted effort to make the boost build be "smart" - in that it should flip to multithreaded mode when the environment favors it. That's pretty vague, but necessarily so. It gets as complicated as weak-linking the pthreads symbols, so that the decision to use MT or ST code is actually deferred to runtime - if pthreads is available at execution time, those symbols will be used, otherwise weakly linked stubs - that do nothing at all - will be used.
The bottom line is that
threading=multi is correct, and harmless, for your scenario, and especially if you are producing a binary you'll distribute to other hosts. If you don't special that, it is highly likely that it will work anyway, due to the build-time and even runtime heuristics, but you do run the chance of silently using empty stub methods, or otherwise using MT-unsafe code. There is little downside to using the right option - but some of the gory details can also be found in the comments to this point, and Igor's reply as well.