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373 lines
12 KiB
Plaintext
---
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slug: 2019/12/release-the-gil
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title: Release the GIL
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date: 2019-12-14 12:00:00
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authors: [bspeice]
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tags: []
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---
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Complaining about the [Global Interpreter Lock](https://wiki.python.org/moin/GlobalInterpreterLock)
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(GIL) seems like a rite of passage for Python developers. It's easy to criticize a design decision
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made before multi-core CPU's were widely available, but the fact that it's still around indicates
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that it generally works [Good](https://wiki.c2.com/?PrematureOptimization)
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[Enough](https://wiki.c2.com/?YouArentGonnaNeedIt). Besides, there are simple and effective
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workarounds; it's not hard to start a
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[new process](https://docs.python.org/3/library/multiprocessing.html) and use message passing to
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synchronize code running in parallel.
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Still, wouldn't it be nice to have more than a single active interpreter thread? In an age of
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asynchronicity and _M:N_ threading, Python seems lacking. The ideal scenario is to take advantage of
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both Python's productivity and the modern CPU's parallel capabilities.
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<!-- truncate -->
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Presented below are two strategies for releasing the GIL's icy grip without giving up on what makes
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Python a nice language to start with. Bear in mind: these are just the tools, no claim is made about
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whether it's a good idea to use them. Very often, unlocking the GIL is an
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[XY problem](https://en.wikipedia.org/wiki/XY_problem); you want application performance, and the
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GIL seems like an obvious bottleneck. Remember that any gains from running code in parallel come at
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the expense of project complexity; messing with the GIL is ultimately messing with Python's memory
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model.
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```python
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%load_ext Cython
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from numba import jit
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N = 1_000_000_000
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```
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## Cython
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Put simply, [Cython](https://cython.org/) is a programming language that looks a lot like Python,
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gets [transpiled](https://en.wikipedia.org/wiki/Source-to-source_compiler) to C/C++, and integrates
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well with the [CPython](https://en.wikipedia.org/wiki/CPython) API. It's great for building Python
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wrappers to C and C++ libraries, writing optimized code for numerical processing, and tons more. And
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when it comes to managing the GIL, there are two special features:
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- The `nogil`
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[function annotation](https://cython.readthedocs.io/en/latest/src/userguide/external_C_code.html#declaring-a-function-as-callable-without-the-gil)
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asserts that a Cython function is safe to use without the GIL, and compilation will fail if it
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interacts with Python in an unsafe manner
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- The `with nogil`
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[context manager](https://cython.readthedocs.io/en/latest/src/userguide/external_C_code.html#releasing-the-gil)
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explicitly unlocks the CPython GIL while active
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Whenever Cython code runs inside a `with nogil` block on a separate thread, the Python interpreter
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is unblocked and allowed to continue work elsewhere. We'll define a "busy work" function that
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demonstrates this principle in action:
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```python
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%%cython
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# Annotating a function with `nogil` indicates only that it is safe
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# to call in a `with nogil` block. It *does not* release the GIL.
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cdef unsigned long fibonacci(unsigned long n) nogil:
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if n <= 1:
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return n
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cdef unsigned long a = 0, b = 1, c = 0
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c = a + b
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for _i in range(2, n):
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a = b
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b = c
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c = a + b
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return c
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def cython_nogil(unsigned long n):
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# Explicitly release the GIL while running `fibonacci`
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with nogil:
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value = fibonacci(n)
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return value
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def cython_gil(unsigned long n):
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# Because the GIL is not explicitly released, it implicitly
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# remains acquired when running the `fibonacci` function
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return fibonacci(n)
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```
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First, let's time how long it takes Cython to calculate the billionth Fibonacci number:
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```python
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%%time
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_ = cython_gil(N);
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```
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> <pre>
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> CPU times: user 365 ms, sys: 0 ns, total: 365 ms
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> Wall time: 372 ms
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> </pre>
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```python
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%%time
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_ = cython_nogil(N);
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```
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> <pre>
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> CPU times: user 381 ms, sys: 0 ns, total: 381 ms
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> Wall time: 388 ms
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> </pre>
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Both versions (with and without GIL) take effectively the same amount of time to run. Even when
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running this calculation in parallel on separate threads, it is expected that the run time will
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double because only one thread can be active at a time:
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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=cython_gil, args=[N])
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t2 = Thread(target=cython_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 641 ms, sys: 5.62 ms, total: 647 ms
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> Wall time: 645 ms
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> </pre>
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However, if the first thread releases the GIL, the second thread is free to acquire it and run in
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parallel:
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```python
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%%time
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t1 = Thread(target=cython_nogil, args=[N])
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t2 = Thread(target=cython_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 717 ms, sys: 372 µs, total: 718 ms
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> Wall time: 358 ms
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> </pre>
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Because `user` time represents the sum of processing time on all threads, it doesn't change much.
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The ["wall time"](https://en.wikipedia.org/wiki/Elapsed_real_time) has been cut roughly in half
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because each function is running simultaneously.
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Keep in mind that the **order in which threads are started** makes a difference!
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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=cython_gil, args=[N])
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t2 = Thread(target=cython_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 667 ms, sys: 0 ns, total: 667 ms
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> Wall time: 672 ms
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> </pre>
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Even though the second thread releases the GIL while running, it can't start until the first has
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completed. Thus, the overall runtime is effectively the same as running two GIL-locked threads.
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Finally, be aware that attempting to unlock the GIL from a thread that doesn't own it will crash the
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**interpreter**, not just the thread attempting the unlock:
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```python
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%%cython
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cdef int cython_recurse(int n) nogil:
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if n <= 0:
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return 0
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with nogil:
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return cython_recurse(n - 1)
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cython_recurse(2)
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```
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> <pre>
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> Fatal Python error: PyEval_SaveThread: NULL tstate
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>
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> Thread 0x00007f499effd700 (most recent call first):
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> File "/home/bspeice/.virtualenvs/release-the-gil/lib/python3.7/site-packages/ipykernel/parentpoller.py", line 39 in run
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> File "/usr/lib/python3.7/threading.py", line 926 in _bootstrap_inner
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> File "/usr/lib/python3.7/threading.py", line 890 in _bootstrap
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> </pre>
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In practice, avoiding this issue is simple. First, `nogil` functions probably shouldn't contain
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`with nogil` blocks. Second, Cython can
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[conditionally acquire/release](https://cython.readthedocs.io/en/latest/src/userguide/external_C_code.html#conditional-acquiring-releasing-the-gil)
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the GIL, so these conditions can be used to synchronize access. Finally, Cython's documentation for
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[external C code](https://cython.readthedocs.io/en/latest/src/userguide/external_C_code.html#acquiring-and-releasing-the-gil)
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contains more detail on how to safely manage the GIL.
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To conclude: use Cython's `nogil` annotation to assert that functions are safe for calling when the
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GIL is unlocked, and `with nogil` to actually unlock the GIL and run those functions.
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## Numba
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Like Cython, [Numba](https://numba.pydata.org/) is a "compiled Python." Where Cython works by
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compiling a Python-like language to C/C++, Numba compiles Python bytecode _directly to machine code_
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at runtime. Behavior is controlled with a special `@jit` decorator; calling a decorated function
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first compiles it to machine code before running. Calling the function a second time re-uses that
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machine code unless the argument types have changed.
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Numba works best when a `nopython=True` argument is added to the `@jit` decorator; functions
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compiled in [`nopython`](http://numba.pydata.org/numba-doc/latest/user/jit.html?#nopython) mode
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avoid the CPython API and have performance comparable to C. Further, adding `nogil=True` to the
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`@jit` decorator unlocks the GIL while that function is running. Note that `nogil` and `nopython`
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are separate arguments; while it is necessary for code to be compiled in `nopython` mode in order to
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release the lock, the GIL will remain locked if `nogil=False` (the default).
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Let's repeat the same experiment, this time using Numba instead of Cython:
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```python
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# The `int` type annotation is only for humans and is ignored
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# by Numba.
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@jit(nopython=True, nogil=True)
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def numba_nogil(n: int) -> int:
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if n <= 1:
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return n
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a = 0
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b = 1
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c = a + b
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for _i in range(2, n):
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a = b
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b = c
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c = a + b
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return c
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# Run using `nopython` mode to receive a performance boost,
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# but GIL remains locked due to `nogil=False` by default.
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@jit(nopython=True)
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def numba_gil(n: int) -> int:
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if n <= 1:
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return n
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a = 0
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b = 1
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c = a + b
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for _i in range(2, n):
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a = b
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b = c
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c = a + b
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return c
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# Call each function once to force compilation; we don't want
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# the timing statistics to include how long it takes to compile.
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numba_nogil(N)
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numba_gil(N);
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```
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We'll perform the same tests as above; first, figure out how long it takes the function to run:
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```python
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%%time
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_ = numba_gil(N)
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```
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> <pre>
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> CPU times: user 253 ms, sys: 258 µs, total: 253 ms
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> Wall time: 251 ms
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> </pre>
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<small>
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Aside: it's not immediately clear why Numba takes ~20% less time to run than Cython for code that should be
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effectively identical after compilation.
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</small>
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When running two GIL-locked threads, the result (as expected) takes around twice as long to compute:
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```python
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%%time
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t1 = Thread(target=numba_gil, args=[N])
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t2 = Thread(target=numba_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 541 ms, sys: 3.96 ms, total: 545 ms
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> Wall time: 541 ms
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> </pre>
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But if the GIL-unlocking thread starts first, both threads run in parallel:
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```python
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%%time
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t1 = Thread(target=numba_nogil, args=[N])
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t2 = Thread(target=numba_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 551 ms, sys: 7.77 ms, total: 559 ms
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> Wall time: 279 ms
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> </pre>
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Just like Cython, starting the GIL-locked thread first leads to poor performance:
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```python
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%%time
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t1 = Thread(target=numba_gil, args=[N])
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t2 = Thread(target=numba_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 524 ms, sys: 0 ns, total: 524 ms
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> Wall time: 522 ms
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> </pre>
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Finally, unlike Cython, Numba will unlock the GIL if and only if it is currently acquired;
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recursively calling `@jit(nogil=True)` functions is perfectly safe:
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```python
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from numba import jit
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@jit(nopython=True, nogil=True)
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def numba_recurse(n: int) -> int:
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if n <= 0:
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return 0
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return numba_recurse(n - 1)
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numba_recurse(2);
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```
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## Conclusion
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Before finishing, it's important to address pain points that will show up if these techniques are
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used in a more realistic project:
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First, code running in a GIL-free context will likely also need non-trivial data structures;
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GIL-free functions aren't useful if they're constantly interacting with Python objects whose access
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requires the GIL. Cython provides
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[extension types](http://docs.cython.org/en/latest/src/tutorial/cdef_classes.html) and Numba
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provides a [`@jitclass`](https://numba.pydata.org/numba-doc/dev/user/jitclass.html) decorator to
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address this need.
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Second, building and distributing applications that make use of Cython/Numba can be complicated.
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Cython packages require running the compiler, (potentially) linking/packaging external dependencies,
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and distributing a binary wheel. Numba is generally simpler because the code being distributed is
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pure Python, but can be tricky since errors aren't detected until runtime.
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Finally, while unlocking the GIL is often a solution in search of a problem, both Cython and Numba
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provide tools to directly manage the GIL when appropriate. This enables true parallelism (not just
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[concurrency](https://stackoverflow.com/a/1050257)) that is impossible in vanilla Python.
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