Doing something like
import numpy as np a = np.random.rand(10**4, 10**4) b = np.dot(a, a)
uses multiple cores, and it runs nicely.
The elements in
a, though, are 64-bit floats (or 32-bit in 32-bit platforms?), and I'd like to multiply 8-bit integer arrays. Trying the following, though:
a = np.random.randint(2, size=(n, n)).astype(np.int8)
results in the dot product not using multiple cores, and thus running ~1000x slower on my PC.
array: np.random.randint(2, size=shape).astype(dtype) dtype shape %time (average) float32 (2000, 2000) 62.5 ms float32 (3000, 3000) 219 ms float32 (4000, 4000) 328 ms float32 (10000, 10000) 4.09 s int8 (2000, 2000) 13 seconds int8 (3000, 3000) 3min 26s int8 (4000, 4000) 12min 20s int8 (10000, 10000) It didn't finish in 6 hours float16 (2000, 2000) 2min 25s float16 (3000, 3000) Not tested float16 (4000, 4000) Not tested float16 (10000, 10000) Not tested
I understand NumPy uses BLAS, which doesn't support integers, but if I use the SciPy BLAS wrappers, ie.
import scipy.linalg.blas as blas a = np.random.randint(2, size=(n, n)).astype(np.int8) b = blas.sgemm(alpha=1.0, a=a, b=a)
the computation is multi-threaded. Now,
blas.sgemm runs with exactly the same timing as
np.dot for float32's, but for non-floats it converts everything to
float32 and outputs floats, which is something
np.dot doesn't do. (In addition,
b is now in
F_CONTIGUOUS order, which is a lesser issue).
So, if I want to do integer matrix multiplication, I have to do one of the following:
- Use NumPy's painfully slow
np.dotand be glad I get to keep the 8-bit integers.
- Use SciPy's
sgemmand use up 4x memory.
- Use Numpy's
np.float16and only use up 2x memory, with the caveat that
np.dotis much slower on float16 arrays than on float32 arrays, more so than int8.
- Find an optimized library for multi-threaded integer matrix multiplication (actually, Mathematica does this, but I'd prefer a Python solution), ideally supporting 1-bit arrays, although 8-bit arrays is also fine... (I'm actually aiming to do multiplication of matrices over the finite field Z/2Z, and I know I can do this with Sage, which is quite Pythonic, but, again, is there something strictly Python?)
Can I follow option 4? Does such a library exist?
Disclaimer: I'm actually running NumPy + MKL, but I've tried a similar test on vanilly NumPy, with similar results.