# A loopless 3D matrix multiplication in python

I am looking to do the following operation in python (numpy).

``````Matrix A is M x N x R
Matrix B is N x 1 x R
``````

Matrix multiply AB = C, where C is a M x 1 x R matrix. Essentially each M x N layer of A (R of them) is matrix multiplied independently by each N x 1 vector in B. I am sure this is a one-liner. I have been trying to use tensordot(), but I that seems to be giving me answers that I don't expect.

I have been programming in Igor Pro for nearly 10 years, and I am now trying to convert pages of it over to python.

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numpy.tensordot() is the right way to do it:

``````a = numpy.arange(24).reshape(2, 3, 4)
b = numpy.arange(12).reshape(3, 1, 4)
c = numpy.tensordot(a, b, axes=[1, 0]).diagonal(axis1=1, axis2=3)
``````

Edit: The first version of this was faulty, and this version computes more han it should and throws away most of it. Maybe a Python loop over the last axis is the better way to do it.

Another Edit: I've come to the conclusion that `numpy.tensordot()` is not the best solution here.

``````c = (a[:,:,None] * b).sum(axis=1)
``````

will be more efficient (though even harder to grasp).

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Thank you for getting back to me so quickly. At the very least, it will get me started. The majority of the code that I am going to try write is matrix operation oriented... so I should really try to understand what is going on here. That being said, there are two parts to the code that confuse me. First is the invoking "axes" inside of tensordot. I am confused about what that actually does, in that, I would expect that a x b should just give you c (as the way I described above) without declaring anything special. Maybe once I understand that, I will see why it is necessary to use .diagonal. –  Jason Mar 18 '11 at 0:55
That is clever... I don't know how long it would have taken me to do something like this (looks like you create a new axis to for multiplication-sum, then essentially recombine later) I really appreciate your time, thanks much! –  Jason Mar 18 '11 at 18:33
Its easier to think of this if the first dimension is the list of matrices (R), and the second one is the common matrix dimension (N) i.e. shape of a is (4, 3, 2) and of b is (4, 3, 1). The multiplication operation then becomes (a * b).sum(axis=1). (a * b) is the multiplication of rows and columns of each elements in the matrix, you need to sum each row to get the final matrix. Just like you multiple matrices by hand. –  whistler Sep 25 '13 at 23:25

Sorry for the necromancy, but this answer can be substantially improved upon, using the invaluable np.einsum.

``````import numpy as np

D,M,N,R = 1,2,3,4
A = np.random.rand(M,N,R)
B = np.random.rand(N,D,R)

print np.einsum('mnr,ndr->mdr', A, B).shape
``````

Note that it has several advantages: first of all, its fast. np.einsum is well-optimized generally, but moreover, np.einsum is smart enough to avoid the creation of an MxNxR temporary array, but performs the contraction over N directly.

But perhaps more importantly, its very readable. There is no doubt that this code is correct; and you could make it a lot more complicated without any trouble.

Note that the dummy 'D' axis can simply be dropped from B and the einsum statement if you wish.

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