Inside the chip design companies that I've worked for, this is called a "quiescent check", but I'm not sure if that's an industry standard name. You implement "instrumentation code" that checks that the system has acheived quiescence. V̶e̶r̶i̶s̶i̶t̶y̶'̶s̶ Cadence's Specman-e tool does this quite elegantly with its objection to end of test mechanism (
raise_objection(MAIN_TEST_DONE)/drop_objection(MAIN_TEST_DONE)). Essentially, monitors throughout throughout the system "raise" an objection at the beginning of simulation ( i.e. increment the counter), then when the simulation runs, they determine that their piece of the DUT is quiescent and they "lower" the objection (i.e. decrement this global counter). When there are no more objections to ending the test, (i.e. the global counter is 0), then
$finish is called. The monitors can raise and lower objections throughout the test, but if and when the counter ever reaches 0, the test is
Universal Verification Methodology (UVM) took up this methodology from Specman and it is described here in their UVM Reference Manual. UVM is implemented with Verilog first and foremost, so you could definitely use their freely available library to implement "quiescent checking". Cadence's Specman UVM reference manual also describes this mechanism at http://support.cadence.com . Unfortunately, Cadence requires that you be a customer before they'll show you their documents and thus you must use a non-Google search engine to find what you want. It's a bit of a pain.