You can assume it will be magically patched if all of the following are true.
- You're sure of the I/O is built on top of standard Python
sockets or other things that
gevent monkeypatches. No files, no native (C) socket objects, etc.
- You pass
patch_select), or you're sure the library doesn't use
select or anything similar.
- The driver doesn't use any (implicit) internal threads. (If the driver does use threads internally,
patch_thread may work, but it may not.)
If you're not sure, it's pretty easy to test—probably easier than reading through the code and trying to work it out. Have one greenlet that just does something like this:
Then have another that runs a slow query against the database. If it's monkeypatched, the looping greenlet will keep printing "running" 10 times/second; if not, the looping greenlet will not get to run while the program is blocked on the query.
So, what do you do if your driver blocks?
The easiest solution is to use a truly concurrent threadpool for DB queries. The idea is that you fire off each query (or batch) as a threadpool job and greenlet-block your
gevent on the completion of that job. (For really simple cases, where you don't need many concurrent queries, you can just spawn a
threading.Thread for each one instead, but usually you can't get away with that.)
If the driver does significant CPU work (e.g., you're using something that runs an in-process cache, or even an entire in-process DBMS like sqlite), you want this threadpool to actually be implemented on top of processes, because otherwise the GIL may prevent your
greenlets from running. Otherwise (especially if you care about Windows), you probably want to use OS threads. (However, this means you can't
patch_threads(); if you need to do that, use processes.)
If you're using
eventlet, and you want to use threads, there's a built-in simple solution called
tpool that may be sufficient. If you're using
gevent, or you need to use processes, this won't work. Unfortunately, blocking a greenlet (without blocking the whole event loop) on a real threading object is a bit different between
gevent, and not documented very well, but the
tpool source should give you the idea. Beyond that part, the rest is just using
futures on pypi if you need this in 2.x or 3.1) to execute the tasks on a
ProcessPoolExecutor. (Or, if you prefer, you can go right to
multiprocessing instead of using
Can you explain why I should use OS threads on Windows?
The quick summary is: If you stick to threads, you can pretty much just write cross-platform code, but if you go to processes, you're effectively writing code for two different platforms.
First, read the Programming guidelines for the
multiprocessing module (both the "All platforms" section and the "Windows" section). Fortunately, a DB wrapper shouldn't run into most of this. You only need to deal with processes via the
ProcessPoolExecutor. And, whether you wrap things up at the cursor-op level or the query level, all your arguments and return values are going to be simple types that can be pickled. Still, it's something you have to be careful about, which otherwise wouldn't be an issue.
Meanwhile, Windows has very low overhead for its intra-process synchronization objects, but very high overhead for its inter-process ones. (It also has very fast thread creation and very slow process creation, but that's not important if you're using a pool.) So, how do you deal with that? I had a lot of fun creating OS threads to wait on the cross-process sync objects and signal the greenlets, but your definition of fun may vary.
tpool can be adapted trivially to a
ppool for Unix, but it takes more work on Windows (and you'll have to understand Windows to do that work).