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First draft of pybind11
Having issues with the Rust code taking *forever*. Going to break out the compiler explorer and see if it's doing something different from C++.
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_posts/2020-06-29-release-the-gil-pt.-2.md
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_posts/2020-06-29-release-the-gil-pt.-2.md
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---
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layout: post
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title: "Release the GIL: Part 2 - Pybind11, PyO3"
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description: "More Python Parallelism"
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category:
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tags: [python]
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---
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I've been continuing experiments with parallelism in Python; while these techniques are a bit niche,
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it's still fun to push the performance envelope. In addition to tools like
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[Cython](https://cython.org/) and [Numba](https://numba.pydata.org/) (covered
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[here](//2019/12/release-the-gil.html)) that attempt to stay as close to Python as possible, other
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projects are available that act as a bridge between Python and other languages. The goal is to make
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cooperation simple without compromising independence.
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In practice, this "cooperation" between languages is important for performance reasons. Code written
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in C++ shouldn't have to care about the Python GIL. However, unless the GIL is explicitly unlocked,
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it will remain implicitly held; though the Python interpreter _could_ be making progress on a
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separate thread, it will be stuck waiting on the current operation to complete. We'll look at some
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techniques below for managing the GIL in a Python extension.
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# Pybind11
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The motto of [Pybind11](https://github.com/pybind/pybind11) is "seamless operability between C++11
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and Python", and they certainly deliver on that. My experience was that it was relatively simple to
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set up a hybrid project where C++ (using CMake) and Python (using setuptools) were able to
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peacefully coexist. We'll examine a simple Fibonacci sequence implementation to demonstrate how
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Python's threading model interacts with Pybind11.
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The C++ implementation is very simple:
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```c++
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#include <cstdint>
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inline std::uint64_t fibonacci(std::uint64_t n) {
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if (n <= 1) {
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return n;
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}
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std::uint64_t a = 0;
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std::uint64_t b = 1;
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std::uint64_t c = 0;
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c = a + b;
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for (std::uint64_t _i = 2; _i < n; _i++) {
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a = b;
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b = c;
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c = a + b;
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}
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return c;
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}
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std::uint64_t fibonacci_gil(std::uint64_t n) {
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// The GIL is held by default when entering C++ from Python, so we need no
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// manipulation here. Interestingly enough, re-acquiring a held GIL is a safe
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// operation (within the same thread), so feel free to scatter
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// `py::gil_scoped_acquire` throughout the code.
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return fibonacci(n);
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}
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std::uint64_t fibonacci_nogil(std::uint64_t n) {
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// Because the GIL is held by default, we need to explicitly release it here.
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// Note that like Cython, releasing the lock multiple times will crash the
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// interpreter.
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py::gil_scoped_release release;
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return fibonacci(n);
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}
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```
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Admittedly, the project setup is significantly more involved than Cython or Numba. I've omitted
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those steps here, but the full project is available at [INSERT LINK HERE].
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```python
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# This number will overflow, but that's OK; our purpose isn't to get an accurate result,
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# it's simply to keep the processor busy.
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N = 1_000_000_000;
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from fibonacci import fibonacci_gil, fibonacci_nogil
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```
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We'll first run each function independently:
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```python
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%%time
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_ = fibonacci_gil(N);
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```
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> <pre>
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> CPU times: user 350 ms, sys: 3.54 ms, total: 354 ms
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> Wall time: 355 ms
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> </pre>
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```python
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%%time
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_ = fibonacci_nogil(N);
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```
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> <pre>
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> CPU times: user 385 ms, sys: 0 ns, total: 385 ms
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> Wall time: 384 ms
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> </pre>
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There's some minor variation in how long it takes to run the code, but not a material difference.
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When running the same function in multiple threads, we expect the run time to double; even though
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there are multiple threads, they effectively run in serial because of the GIL:
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```python
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%%time
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from threading import Thread
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# Create the two threads to run on
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t1 = Thread(target=fibonacci_gil, args=[N])
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t2 = Thread(target=fibonacci_gil, args=[N])
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# Start the threads
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t1.start(); t2.start()
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# Wait for the threads to finish
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t1.join(); t2.join()
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```
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> <pre>
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> CPU times: user 709 ms, sys: 0 ns, total: 709 ms
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> Wall time: 705 ms
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> </pre>
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However, if one thread unlocks the GIL first, then the threads will execute in parallel:
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```python
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%%time
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t1 = Thread(target=fibonacci_nogil, args=[N])
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t2 = Thread(target=fibonacci_gil, args=[N])
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t1.start(); t2.start()
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t1.join(); t2.join()
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```
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> <pre>
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> CPU times: user 734 ms, sys: 7.89 ms, total: 742 ms
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> Wall time: 372 ms
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> </pre>
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While it takes the same amount of CPU time to compute the result ("user" time), the run time ("wall"
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time) is cut in half because the code is now running in parallel.
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```python
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%%time
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# Note that the GIL-locked version is started first
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t1 = Thread(target=fibonacci_gil, args=[N])
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t2 = Thread(target=fibonacci_nogil, args=[N])
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t1.start(); t2.start()
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t1.join(); t2.join()
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```
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> <pre>
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> CPU times: user 736 ms, sys: 0 ns, total: 736 ms
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> Wall time: 734 ms
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> </pre>
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Finally, it's import to note that scheduling matters; in this example, threads run in serial because
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the GIL-locked thread is started first.
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