While this isn't entirely clear from the docs, multiprocessing synchronization primitives do in fact synchronize threads as well.
For example, if you run this code:
lock = multiprocessing.Lock()
for _ in range(10):
t1 = threading.Thread(target=f, args=['1'])
t2 = threading.Thread(target=f, args=['2'])
… the output will always be
22222222221111111111, not a mixture of the two.
The locks are implemented on top of Win32 kernel sync objects on Windows, semaphores on POSIX platforms that support them, and not implemented at all on other platforms. (You can test this with
import multiprocessing.semaphore, which will raise an
ImportError on other platforms, as explained in the docs.)
That being said, it's certainly safe to have two levels of locks, as long as you always use them in the right order—that is, never grab the
threading.Lock unless you can guarantee that your process has the
If you do this cleverly enough, it can have performance benefits. (Cross-process locks on Windows, and on some POSIX platforms, can be orders of magnitude slower than intra-process locks.)
If you just do it in the obvious way (only do
with threadlock: inside
with processlock: blocks), it obviously won't help performance, and in fact will slow things down a bit (although quite possibly not enough to measure), and it won't add any direct benefits. Of course your readers will know that your code is correct even if they don't know that
multiprocessing locks work between threads, and in some cases debugging intraprocess deadlocks can be a lot easier than debugging interprocess deadlocks… but I don't think either of those is a good enough reason for the extra complexity in most cases.