# Looping over np.einsum many times... Is there a faster way?

I have a likelihood function that I am trying to sample with MCMC. I have used no for loops in the log likelihood itself, but I do call `np.einsum()` once.

Here's a sample of what my current code looks like:

``````A = np.random.rand(4,50,60,200) # Random NDarray
B = np.random.rand(200,1000,4)  # Random NDarray
out = np.einsum('ijkl,lui->jkui', A, B, optimize="optimal")
``````

The output `out` has dimensions (50,60,1000,4). This calculation is a bit too slow to allow for efficient MCMC sampling (~4 seconds on my machine), is there any way to speed it up? One useful piece of information is that for each call of the log-likelihood function, while the actual values in the arrays A and B are changing, the dimensions of each array remains fixed. I'd imagine this could be useful in speeding things up, since the same elements are always being multiplied together.

Well one of the axes stays aligned in `A` (first one) and `B` (last one) and stays in output as well (last one) and is a very small looping number of `4`. So, we could simply loop over that one with with `np.tensordot` for a tensor sum-reduction. The benefit of `4x` lesser memory congestion when working with such large datasets might overcome the 4x looping because the compute per iteration is also `4x` lesser.

Thus, a solution with `tensordot` would be -

``````def func1(A, B):
out = np.empty(A.shape[1:3] + B.shape[1:])
for i in range(len(A)):
out[...,i] = np.tensordot(A[i], B[...,i],axes=(-1,0))
return out
``````

Timings -

``````In : A = np.random.rand(4,50,60,200) # Random NDarray
...: B = np.random.rand(200,1000,4)  # Random NDarray
...: out = np.einsum('ijkl,lui->jkui', A, B, optimize="optimal")

# Einsum solution without optimize
In : %timeit np.einsum('ijkl,lui->jkui', A, B)
2.89 s ± 109 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)

# Einsum solution with optimize
In : %timeit np.einsum('ijkl,lui->jkui', A, B, optimize="optimal")
2.79 s ± 9.31 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)

# @Paul Panzer's soln
In : %timeit np.stack([np.tensordot(a,b,1) for a,b in zip(A,B.transpose(2,0,1))],-1)
183 ms ± 6.08 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)

In : %timeit func1(A,B)
158 ms ± 3.35 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)
``````

Just to re-iterate the importance of memory-congestion and compute requirement, let's say we want to sum-reduce the last axis of length `4` as well, then we will see a noticeable difference in timings for `optimal` version -

``````In : %timeit np.einsum('ijkl,lui->jkui', A, B, optimize="optimal")
2.76 s ± 9.36 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)

In : %timeit np.einsum('ijkl,lui->jku', A, B, optimize="optimal")
93.8 ms ± 3.3 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)
``````

So, in that case, it would be better to go with `einsum`.

### Specific to given problem

Given that dimensions of `A` and `B` stay the same, the array-initialization with `out = np.empty(A.shape[1:3] + B.shape[1:])` could be done as a one-time affair and loop through each call of the log-likelihood function with the proposed looping over to use `tensordot` and update output `out`.

• @Jsn If you are new to `tensordot`, this could be helpful - stackoverflow.com/questions/41870228 for some examples with it. Jul 14, 2020 at 19:12
• That memory-congestion insight is instructive. I wasn't aware that the effects are so drastic. Jul 14, 2020 at 21:10
• The memory-congestion example is more of an einsum vs BLAS issue. 78 will reorganize the tensors and perform a TDOT, 79 isn't possible to call a TDOT so it uses einsum loops. Jul 15, 2020 at 20:02

Even when used in a small loop `tensordot` is more than 10x faster:

``````timeit(lambda:np.einsum('ijkl,lui->jkui', A, B, optimize="optimal"),number=5)/5
# 3.052245747600682
timeit(lambda:np.stack([np.tensordot(a,b,1) for a,b in zip(A,B.transpose(2,0,1))],-1),number=10)/10
# 0.23842503569903784

out_td = np.stack([np.tensordot(a,b,1) for a,b in zip(A,B.transpose(2,0,1))],-1)
out_es = np.einsum('ijkl,lui->jkui', A, B, optimize="optimal")
np.allclose(out_td,out_es)
# True
``````