3

I have 2 arrays currently with shapes v1=(3000,3) and v2=(3,2,3000). The 3000 is a time dimension so v1 has 3000 (1,3) samples and v2 has 3000 (3,2) samples. I wish to do matrix multiplication and broadcast along the 3000 dimension so that I get 3000 (1,2) vectors in return.

I have tried reshaping so that v1 = (1,3,3000) and v2 = (3,2,300) which gives an error saying that the shapes are not aligned.

code:

v1 = np.ones((1,3,3000)) +1
v2 = np.ones((3,2,3000)) - 0.5
np.dot(v1,v2)
4

With v1 of shape (3000,3) and v2 as (3,2,3000), we can use np.einsum -

np.einsum('ij,jki->ik',v1,v2)

This gives us an output of shape (3000,2).

We could play around with the optimize arg in np.einsum. With optimize = True, it leverages BLAS internally and with optimize = False resorts to simple C-loops. That BLAS way requires some setting up work too. So, with decent lengths of axes that undergo sum-reductions, we might want to set that flag as True and False otherwise. In this case, it seems those axes are really short, so we are probably better off with the default : optimize = False input.

  • is this equivalent to doing matrix multiplication? I tried to read the docs on einsum but they puzzled me. – seanysull Feb 19 at 8:32
  • @seanysull It's performing matrix multiplication on tensors(more than 2 dims) under the hoods leveraging BLAS with that optimize flag set as True, same as np.dot. – Divakar Feb 19 at 8:34
  • @Divakar Do you know the reason why using optimize=True consumes more time than when not using it? (please see the timings in my code below). Could it be possible that it spends lot of time optimizing the code? – kmario23 Feb 19 at 11:53
  • @kmario23 What version of NumPy are you on? – Divakar Feb 19 at 12:03
  • 1
    @You are right. Edited question with comments on the same. Thanks for pointing it out. – Divakar Feb 19 at 12:30
3

I'd suggest you to not use optimize=True flag because it's in-efficient, for some strange reason. Also, I'd recommend you to explicitly promote the 2D-array to 3D, perform batch matrix multiplication and then squeeze the singleton dimension of the resultant array, if you at the end need a 2D array as the final result. Please find the code below:

# sample arrays
In [25]: v1 = np.random.random_sample((3000, 3))
In [26]: v2 = np.random.random_sample((3, 2, 3000))

# Divakar's approach
In [27]: %timeit np.einsum('ij,jki->ik',v1,v2, optimize=True)
80.7 µs ± 792 ns per loop (mean ± std. dev. of 7 runs, 10000 loops each)

# needed for future use
In [28]: res_optimized = np.einsum('ij,jki->ik',v1,v2, optimize=True)

# promoting to 3D array and swapping axes
In [29]: v1 = v1[:, np.newaxis, :]
In [30]: v2 = np.moveaxis(v2, 2, 0)

# perform batch matrix multiplication
In [31]: %timeit np.einsum("bij, bjk -> bik", v1, v2)
47.9 µs ± 496 ns per loop (mean ± std. dev. of 7 runs, 10000 loops each)

# for sanity checking
In [32]: res = np.einsum("bij, bjk -> bik", v1, v2)

In [33]: res.shape, res_optimized.shape
Out[33]: ((3000, 1, 2), (3000, 2))

# squeeze the singleton dimension and perform sanity check with Divakar's approach
In [34]: np.allclose(res.squeeze(), res_optimized)
Out[34]: True

So, as we can see from the above timings, we gain approx. 2x speedup by not using optimize=True flag. Also, explicitly shaping the arrays to 3D gives bit more understanding about what's going on when we use numpy.einsum().

Note: timings were performed using the latest NumPy version '1.16.1'


P.S. Read more about Understanding NumPy einsum()

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.