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So, basically there seems to be massive confusion/ambiguity over when exactly PyEval_InitThreads() is supposed to be called, and what accompanying API calls are needed. The official Python documentation is unfortunately very ambiguous. There are already many questions on stackoverflow regarding this topic, and indeed, I've personally already asked a question almost identical to this one, so I won't be particularly surprised if this is closed as a duplicate; but consider that there seems to be no definitive answer to this question. (Sadly, I don't have Guido Van Rossum on speed-dial.)

Firstly, let's define the scope of the question here: what do I want to do? Well... I want to write a Python extension module in C that will:

  1. Spawn worker threads using the pthread API in C
  2. Invoke Python callbacks from within these C threads

Okay, so let's start with the Python docs themselves. The Python 3.2 docs say:

void PyEval_InitThreads()

Initialize and acquire the global interpreter lock. It should be called in the main thread before creating a second thread or engaging in any other thread operations such as PyEval_ReleaseThread(tstate). It is not needed before calling PyEval_SaveThread() or PyEval_RestoreThread().

So my understanding here is that:

  1. Any C extension module which spawns threads must call PyEval_InitThreads() from the main thread before any other threads are spawned
  2. Calling PyEval_InitThreads locks the GIL

So common sense would tell us that any C extension module which creates threads must call PyEval_InitThreads(), and then release the Global Interpreter Lock. Okay, seems straightforward enough. So prima facie, all that's required would be the following code:

PyEval_InitThreads(); /* initialize threading and acquire GIL */
PyEval_ReleaseLock(); /* Release GIL */

Seems easy enough... but unfortunately, the Python 3.2 docs also say that PyEval_ReleaseLock has been deprecated. Instead, we're supposed to use PyEval_SaveThread in order to release the GIL:

PyThreadState* PyEval_SaveThread()

Release the global interpreter lock (if it has been created and thread support is enabled) and reset the thread state to NULL, returning the previous thread state (which is not NULL). If the lock has been created, the current thread must have acquired it.

Er... okay, so I guess a C extension module needs to say:

PyThreadState* st = PyEval_SaveThread();

Indeed, this is exactly what this stackoverflow answer says. Except when I actually try this in practice, the Python interpreter immediately seg-faults when I import the extension module.    Nice.

Okay, so now I'm giving up on the official Python documentation and turning to Google. So, this random blog claims all you need to do from an extension module is to call PyEval_InitThreads(). Of course, the documentation claims that PyEval_InitThreads() acquires the GIL, and indeed, a quick inspection of the source code for PyEval_InitThreads() in ceval.c reveals that it does indeed call the internal function take_gil(PyThreadState_GET());

So PyEval_InitThreads() definitely acquires the GIL. I would think then that you would absolutely need to somehow release the GIL after calling PyEval_InitThreads().   But how? PyEval_ReleaseLock() is deprecated, and PyEval_SaveThread() just inexplicably seg-faults.

Okay... so maybe for some reason which is currently beyond my understanding, a C extension module doesn't need to release the GIL. I tried that... and, as expected, as soon as another thread attempts to acquire the GIL (using PyGILState_Ensure), the program hangs from a deadlock. So yeah... you really do need to release the GIL after calling PyEval_InitThreads().

So again, the question is: how do you release the GIL after calling PyEval_InitThreads()?

And more generally: what exactly does a C-extension module have to do to be able to safely invoke Python code from worker C-threads?

share|improve this question
related: Python code calls C library that create OS threads, which eventually call Python callbacks. See the example c_extension module there (its purpose is to trigger an error in threading while being "correct" to expose a bug in threading implementation. It fails to trigger an error on Python 3). – J.F. Sebastian Mar 18 '13 at 6:52
Did you manage to solve this? I'm having the exact same problem and my c application keeps giving segfaults no matter what I do – João Pereira May 13 '14 at 15:34
up vote 5 down vote accepted

The short answer: you shouldn't care about releasing the GIL after calling PyEval_InitThreads, it will never again be released, except temporarily.

In Python threading, someone always holds the GIL. It can relinquish it temporarily with PyEval_SaveThread, but it will get it back at PyEval_RestoreThread (the same applies Py_{BEGIN,END}_ALLOW_THREADS macros). Since someone always must hold the GIL, it only makes sense for the call that materializes the lock into the system to also acquire it.

Therefore your C extension should simply call PyEval_InitThreads in its init function. The current thread will have the GIL until it relinquishes it to someone else—this is how Python threading works. When your worker C threads need to invoke Python (or call anything from the Python API, including Py_INCREF), just wrap the code in the usual pair of PyGILState_Ensure and PyGILState_Release. Since the GIL is recursive, this will work even if the current thread is already holding it.

share|improve this answer
PyGILState_Ensure()/PyGILState_Release() should be used to invoke Python from a C thread instead of PyEval_{Save,Restore}Thread() See Thread State and the Global Interpreter Lock – J.F. Sebastian Mar 18 '13 at 8:29
@J.F.Sebastian Agreed, I've now edited the answer to advertise the correct API. – user4815162342 Mar 18 '13 at 9:08
@Channel72 Why would it deadlock? It will only wait as long as necessary to acquire the GIL. The main thread must relinquish the GIL sooner or later—it will either entering a blocking syscall that releases the GIL, or the interpreter will release it automatically after executing a number of bytecode instructions. – user4815162342 Mar 18 '13 at 15:07
genuinely curious about the downvote. some explanation? – user4815162342 Mar 19 '13 at 7:31
@user4815162342 - It would deadlock if the thread that calls PyEval_InitThreads doesn't actually do anything with Python. It happened in an Init call of some sort, so it didn't necessarily need to call Python at that point. So does that thread just go about its business and ignore the GIL lock for the rest of the program execution? – DougN Apr 17 '13 at 19:31

I have seen symptoms similar to yours: deadlocks if I only call PyEval_InitThreads(), because my main thread never calls anything from Python again, and segfaults if I unconditionally call something like PyEval_SaveThread(). The symptoms depend on the version of Python and on the situation: I am developing a plug-in that embeds Python for a library that can be loaded as part of a Python extension. The code needs therefore to run independent of whether it is loaded by Python as main.

The following worked for be with both python2.7 and python3.4, and with my library running within Python and outside of Python. In my plug-in init routine, which is executed in the main thread, I run:

  if (!PyEval_ThreadsInitialized()) {
    PyThreadState* mainPyThread = PyEval_SaveThread();

(mainPyThread is actually some static variable, but I don't think that matters as I never need to use it again).

Then I create threads using pthreads, and in each function that needs to access the Python API, I use:

  PyGILState_STATE gstate;
  gstate = PyGILState_Ensure();
  // Python C API calls
share|improve this answer

The suggestion to call PyEval_SaveThread works

PyThreadState* st = PyEval_SaveThread();

However to prevent crash when module is imported, ensure Python APIs to import are protected using

PyGILState_Ensure and PyGILState_Release


PyGILState_STATE gstate = PyGILState_Ensure();
PyObject *pyModule_p = PyImport_Import(pyModuleName_p);
share|improve this answer

To quote above:

The short answer: you shouldn't care about releasing the GIL after calling PyEval_InitThreads...

Now, for a longer answer:

I'm limiting my answer to be about Python extensions (as opposed to embedding Python). If we are only extending Python, than any entry point into your module is from Python. This by definition means that we don't have to worry about calling a function from a non-Python context, which makes things a bit simpler.

If threads have NOT be initialized, then we know there is no GIL (no threads == no need for locking), and thus "It is not safe to call this function when it is unknown which thread (if any) currently has the global interpreter lock" does not apply.

if (!PyEval_ThreadsInitialized())

After calling PyEval_InitThreads(), a GIL is created and assigned... to our thread, which is the thread currently running Python code. So all is good.

Now, as far as our own launched worker "C"-threads, they will need to ask for the GIL before running relevant code: so their common methodology is as follows:

// Do only non-Python things up to this point
PyGILState_STATE state = PyGILState_Ensure();
// Do Python-things here, like PyRun_SimpleString(...)
// ... and now back to doing only non-Python things

We don't have to worry about deadlock any more than normal usage of extensions. When we entered our function, we had control over Python, so either we were not using threads (thus, no GIL), or the GIL was already assigned to us. When we give control back to the Python run-time by exiting our function, the normal processing loop will check the GIL and hand control of as appropriate to other requesting objects: including our worker threads via PyGILState_Ensure().

All of this the reader probably already knows. However, the "proof is in the pudding". I've posted a very-minimally-documented example that I wrote today to learn for myself what the behavior actually was, and that things work properly. Sample Source Code on GitHub

I was learning several things with the example, including CMake integration with Python development, SWIG integration with both of the above, and Python behaviors with extensions and threads. Still, the core of the example allows you to:

  • Load the module -- 'import annoy'
  • Load zero or more worker threads which do Python things -- 'annoy.annoy(n)'
  • Clear any worker threads -- 'annon.annoy(0)'
  • Provide thread cleanup (on Linux) at application exit

... and all of this without any crashes or segfaults. At least on my system (Ubuntu Linux w/ GCC).

share|improve this answer

You don't need to call that in your extension modules. That's for initializing the interpreter which has already been done if your C-API extension module is being imported. This interface is to be used by embedding applications.

When is PyEval_InitThreads meant to be called?

share|improve this answer
no, you need to call PyEval_InitThreads if you are planning to do Python callbacks from multiple non-Python threads (as the answer that you've linked says) – J.F. Sebastian Mar 18 '13 at 6:46
After looking at the source a bit, it would appear that you are technically correct. However, the documentation makes no such suggestion for use, so I would avoid using the interface in such a way. In fact, states that subsequent calls are a no-op. – jwp Mar 18 '13 at 19:53
Okay, I guess C-API extension modules that are demanding Python threads would desire to call this to make sure that the gil is initialized. Personally, if an embedding application did not initialize Python threading, I would think twice about running threads. – jwp Mar 18 '13 at 19:58

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