Look at this: http://www.boost.org/doc/libs/1_44_0/libs/regex/doc/html/boost_regex/configuration/algorithm.html
The existence of a recursive/non-recursive distinction is a pretty strong suggestion that BOOST is not necessarily a linear-time discrete finite-state machine. Therefore, there's a good chance you can do better for your particular problem.
The best answer depends quite a bit on how many haystacks you have and the minimum size of a needle. If the smallest needle is longer than a few characters, you may be able to do a little bit better than a generalized regex library.
Basically all string searches work by testing for a match at the current position (cursor), and if none is found, then trying again with the cursor slid farther to the right.
Rabin-Karp builds a DFSM out of the string (or strings) for which you are searching so that the test and the cursor motion are combined in a single operation. However, Rabin-Karp was originally designed for a single needle, so you would need to support backtracking if one match could ever be a proper prefix of another. (Remember that for when you want to reuse your code.)
Another tactic is to slide the cursor more than one character to the right if at all possible. Boyer-Moore does this. It's normally built for a single needle. Construct a table of all characters and the rightmost position that they appear in the needle (if at all). Now, position the cursor at len(needle)-1. The table entry will tell you (a) what leftward offset from the cursor that the needle might be found, or (b) that you can move the cursor len(needle) farther to the right.
When you have more than one needle, the construction and use of your table grows more complicated, but it still may possibly save you an order of magnitude on probes. You still might want to make a DFSM but instead of calling a general search method, you call does_this_DFSM_match_at_this_offset().
Another tactic is to test more than 8 bits at a time. There's a spam-killer tool that looks at 32-bit machine words at a time. It then does some simple hash code to fit the result into 12 bits, and then looks in a table to see if there's a hit. You have four entries for each pattern (offsets of 0, 1, 2, and 3 from the start of the pattern) and then this way despite thousands of patterns in the table they only test one or two per 32-bit word in the subject line.
So in general, yes, you can go faster than regexes WHEN THE NEEDLES ARE CONSTANT.