I am doing some performance analysis, and i wonder, whether numpy vectorizes its standard array operations, when the datatype is known (double).

a, b = (some numpy arrays)
c = a + b #Is this vectorized?

Edit: Is this operation vectorized, i.e. will the computation consist of SIMD operations?

  • 3
    well... yes? Why would you think otherwise?
    – Julien
    Jul 6 '17 at 9:06
  • 6
    "Vectorized" in what sense? The usual sense in which the word is used in a NumPy context may not be the sense you're thinking of, if you're thinking of hardware-level SIMD operations. Jul 6 '17 at 9:07

Yes, they are.

 * This file is for the definitions of simd vectorized operations.
 * Currently contains sse2 functions that are built on amd64, x32 or
 * non-generic builds (CFLAGS=-march=...)
 * In future it may contain other instruction sets like AVX or NEON     detected
 * at runtime in which case it needs to be included indirectly via a file
 * compiled with special options (or use gcc target attributes) so the binary
 * stays portable.

Link: Numpy simd.inc.src on github.

  • Actually, NumPy does not. Here is an article that goes through NumPy code and demonstrating it through Matrix multiplication. Jan 14 at 23:52
  • 2
    @QuaziIrfan Article is titled with word "vectorization", but it really looks only for "parallelization", and only conclusion author made: "it does not capitalize on parallelization". So it doesn't really mean anything about SIMD.
    – Rustam A.
    May 29 at 20:49
  • Does it mean only float16 or float32 benefit from SIMD on a x86 architecture? Oct 18 at 14:11

i notice there is a comment from Quazi Irfan on henrikstroem's answer,which says numpy doesn't exploit vectorization and cites a blog in which the author made a "proof" by experiments.

so i go through the blog and found there is a gap may conduct a different conclusion:for numpy-array a and b,the arithmetic a*b is different with np.dot(a,b).the arithmetic(a*b) which the blog author tested is just scalar multiplication,not a matrix multiplication(np.dot(a,b)),even not a vector inner product.but the author still used a*b to compare with the original experiment which runs np.dot(a,b).the complexity of these two arithmetics are so different!

numpy certainly exploits vectorized by SIMD and BLAS,which can be found in its source code.the official numpy distribution supports a set of parallel manipulation(like np.dot),but not every functions(like np.where,np.mean).the blog author may choose an inappropriate function(a unvectorized function) to compare.

we can also see that in respect of multi-cores CPU usage.when executing numpy.dot(),all the cores are performing a high usage.Hence numpy must have vectorized(by BLAS) to avoid just using a single core because of the CPython's GIL restriction.

  • 1) Could you provide the blog post? 2) Thread-level parallelism has nothing to do with instruction-level paralelism.
    – hr0m
    Dec 2 at 21:21

Take a look at basic example

import numpy as np

x = np.array([1, 2, 3], np.int32)
print (type(x))
y = np.array([6, 7, 8], np.int32)
print (type(y))

Now we are adding up these two arrays

print (z)
print (type(z))

As a result we have

<class 'numpy.ndarray'>
<class 'numpy.ndarray'>
[ 7  9 11]
<class 'numpy.ndarray'>

Vectorised,yes they are.But the term vector has different meaning in mathematics and physics,and we are using arrays as mathematical abstraction.

  • I didn't downvote, but I don't understand how this answer actually addresses the OP's question. May 30 '20 at 19:40
  • 2
    @EJoshuaS-ReinstateMonica Check the edit of the question, this answer was posted for original question which did not state it was asking about SIMD vectorization, so this answer was valid before the edit.
    – Kaaf
    Jul 4 '20 at 13:08

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