Python implementation of Klong language.
Project description
KlongPy
KlongPy is a vectorized port of Klong, making it a blazingly fast array language that supports direct Python integration.
NumPy is used as the runtime target because it itself is an Iverson Ghost, or rather a descendent of APL, making the mapping from Klong to NumPy relatively straightforward.
Using NumPy also means that, via CuPy, both CPU and GPU backends are supported (where possible, see Status section).
Klong was created by Nils M Holm and he has also written a Klong Book.
Related
Overview
KlongPy brings together the Klong terse array language notation with the performance of NumPy. I wanted to use Klong but I also wanted it to be a fast as possible. Bonus is the ability to mix Klong with Python libraries making it easy to pick and choose the tools as appropriate.
Here's simple example of mixing Python and KlongPy to compute average of a 1B entry array.
First, let's look at how average is computed in Klong:
{(+/x)%#x}
which directly translates to (right to left): length of x divides sum over x.
Now, with that in hand, we can try it in the REPL:
Welcome to KlongPy REPL
author: Brian Guarraci
repo : https://github.com/briangu/klongpy
crtl-c to quit
?> avg::{(+/x)%#x}
:monad
?> avg(100)
49.5
Now let's time it. First we'll run it once and see it takes about 374us, then we'll run it 100 times. ?> ]T avg(!100) 0.0003741057589650154 >? ]T:100 avg(!100) 0.007682837080210447
Let's compare CPU vs GPU backends:
```python
import time
from klongpy.backend as np
from klongpy import KlongInterpreter
# instantiate the KlongPy interpeter
klong = KlongInterpreter()
# create a billion random uniform values [0,1)
data = np.random.rand(10**9)
# define average function in Klong
# Note the '+/' (sum over) uses np.add.reduce under the hood
klong('avg::{(+/x)%#x}')
# make generated data available in KlongPy as the 'data' variable
klong['data'] = data
# run Klong average function and return the result back to Python
start = time.perf_counter_ns()
r = klong('avg(data)')
stop = time.perf_counter_ns()
seconds = (stop - start) / (10**9)
print(f"avg={np.round(r,6)} in {round(seconds,6)} seconds")
Run (CPU)
$ python3 tests/perf_avg.py
avg=0.5 in 0.16936 seconds
Run (GPU)
$ USE_GPU=1 python3 tests/perf_avg.py
avg=0.500015 in 0.027818 seconds
Python integration
KlongPy supports direct Python integration, making it easy to mix Klong with Python and use it in the most suitable scenarios. For example, KlongPy can be part of an ML/Pandas workflow or be part of the website backend.
Extending KlongPy with custom functions and moving data in / out of the KlongPy interpeter is easy since the interpreter operates as a dictionary. The dictionary contents are the current KlongPy state.
Data generated elsewhere can be set in KlongPy and seamlessly accessed and processed via Klong language. Also, Python lambdas or functions may be exposed directly as Klong functions, allowing easy extensions to the Klong language.
Function example
klong = KlongInterpreter()
klong['f'] = lambda x, y, z: x*1000 + y - z
r = klong('f(3; 10; 20)')
assert r == 2990
Data example
data = np.arange(10*9)
klong['data'] = data
r = klong('1+data')
assert r == 1 + data
Variables may be directly retrieved from KlongPy context:
klong('Q::1+data')
Q = klong['Q']
print(Q)
Performance
The Klong language is simple, so the overhead is low. The bulk of the compute time will likely be spent in NumPy doing actual work.
Here's a contrived rough benchmark to show the magnitude differences between Python, KlongPy (CPU + GPU) and Numpy (CPU).
Spoiler: GPU-backed KlongPy is about 790x faster than naive Python and 36x faster than NumPy-backed KlongPy.
Python
def python_vec(number=100):
r = timeit.timeit(lambda: [2 * (1 + x) for x in range(10000000)], number=number)
return r/number
KlongPy
# NumPy and CuPy (CuPy is enabled via USE_GPU=1 environment variable
def klong_vec(number=100):
klong = KlongInterpreter()
r = timeit.timeit(lambda: klong("2*1+!10000000"), number=number)
return r/number
NumPy (explicit usage)
def NumPy_vec(number=100):
r = timeit.timeit(lambda: np.multiply(np.add(np.arange(10000000), 1), 2), number=number)
return r/number
Results
CPU (AMD Ryzen 9 7950x)
$ python3 tests/perf_vector.py
Python: 0.369111s
KlongPy USE_GPU=None: 0.017946s
Numpy: 0.017896s
Python / KlongPy => 20.568334
Numpy / KlongPy => 0.997245
GPU (Same CPU w/ NVIDIA GeForce RTX 3090)
$ USE_GPU=1 python3 tests/perf_vector.py
Python: 0.364893s
KlongPy USE_GPU=1: 0.000461s
NumPy: 0.017053s
Python / KlongPy => 790.678069
Numpy / KlongPy => 36.951443
Installation
CPU
$ pip3 install klongpy
GPU support
Choose your CuPy prebuilt binary or from source:
'cupy' => build from source
'cuda12x' => "cupy-cuda12x"
'cuda11x' => "cupy-cuda11x"
'cuda111' => "cupy-cuda111"
'cuda110' => "cupy-cuda110"
'cuda102' => "cupy-cuda102"
'rocm-5-0' => "cupy-rocm-5-0"
'rocm-4-3' => "cupy-rocm-4-3"
$ pip3 install klongpy[cupy]
Everything
$ pip3 install klongpy[cupy,repl]
Develop
$ git clone https://github.com/briangu/klongpy.git
$ cd klongpy
$ python3 setup.py develop
REPL
KlongPy has a REPL similar to Klong.
$ pip3 install klongpy[repl]
$ rlwrap kgpy
Welcome to KlongPy REPL
author: Brian Guarraci
repo : https://github.com/briangu/klongpy
crtl-c to quit
?> 1+1
2
>? "hello, world!"
hello, world!
?> prime::{&/x!:\2+!_x^1%2}
:monad
?> prime(4)
0
?> prime(251)
1
?> ]T prime(251)
0.0005430681630969048
Read about the prime example here.
Status
KlongPy aims to be a complete implementation of klong. It currently passes all of the integration tests provided by klong.
Since CuPy is not 100% compatible with NumPy, there are currently some gaps in KlongPy between the two backends. Notably, strings are supported in CuPy arrays so KlongPy GPU support currently is limited to math.
Primary ongoing work includes:
- Actively switch between CuPy and NumPy when incompatibilities are present
- Additional syntax error help
- Additional tests to
- ensure proper vectorization
- increase Klong grammar coverage
- Make REPL (kgpy) compatible with original Klong (kg) REPL
Differences from Klong
The main difference between Klong and KlongPy is that KlongPy doesn't infinite precision because it's backed by NumPy which is restricted to doubles.
Running tests
python3 -m unittest
Unused operators
The following operators are yet to be used:
:! :& :, :< :> :?
Acknowledgement
HUGE thanks to Nils M Holm for his work on Klong and providing the foundations for this interesting project.
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