I have a k*n matrix X, and an k*k matrix A. For each column of X, I'd like to calculate the scalar

X[:, i].T.dot(A).dot(X[:, i])

(or, mathematically, Xi' * A * Xi).

Currently, I have a for loop:

out = np.empty((n,))
for i in xrange(n):
    out[i] = X[:, i].T.dot(A).dot(X[:, i])

but since n is large, I'd like to do this faster if possible (i.e. using some NumPy functions instead of a loop).


3 Answers 3


This seems to do it nicely: (X.T.dot(A)*X.T).sum(axis=1)

Edit: This is a little faster. np.einsum('...i,...i->...', X.T.dot(A), X.T). Both work better if X and A are Fortran contiguous.

  • Appears to handily beat my original code: for n=10000, k=10, my code is 76.2ms, the new code is 1.64ms. Nice!
    – nneonneo
    Aug 30, 2013 at 22:32

You can use the numpy.einsum:


This will get the same result. Let's see if it is much faster:

enter image description here

Looks like dot is still the fastest option, particularly because it uses threaded BLAS, as opposed to einsum which runs on one core.

import perfplot
import numpy as np

def setup(n):
    k = n
    x = np.random.random((k, n))
    A = np.random.random((k, k))
    return x, A

def loop(data):
    x, A = data
    n = x.shape[1]
    out = np.empty(n)
    for i in range(n):
        out[i] = x[:, i].T.dot(A).dot(x[:, i])
    return out

def einsum(data):
    x, A = data
    return np.einsum('ji,jk,ki->i', x, A, x)

def dot(data):
    x, A = data
    return (x.T.dot(A)*x.T).sum(axis=1)

    kernels=[loop, einsum, dot],
    n_range=[2**k for k in range(10)],
    xlabel='n, k'
  • 1
    This is considerably slower for large dimension on modern processors due to its in ability to use a threaded BLAS.
    – Daniel
    Aug 30, 2013 at 22:19
  • @Ophion good point, but I believe it will still be faster than the Python for loop... something worth checking Aug 30, 2013 at 22:23
  • Python for loop cython/numpy for loop does not matter. The time really isnt in the loop.
    – Daniel
    Aug 30, 2013 at 22:24
  • I don't have threaded BLAS (though I should obviously get it at some point). For n=10000, this outperforms my original code (76.2ms vs. 1.48ms).
    – nneonneo
    Aug 30, 2013 at 22:33
  • 2
    Hm, you may be right. Thanks for the einsum link; it's nice to know what it can do. Too bad it is not the fastest solution. (Very surprising that it is faster than @IanH's solution for n=10000, k=10 on one core, though)
    – nneonneo
    Aug 30, 2013 at 22:43

You can't do it faster unless you parallelize the whole thing: One thread per column. You'll still use loops - you can't get away from that.

Map reduce is a nice way to look at this problem: map step multiples, reduce step sums.

  • 4
    Of course I can't get faster from a complexity standpoint, but avoiding Python loops (in favour of NumPy constructs) usually provides a speedup simply by avoiding slower Python code.
    – nneonneo
    Aug 30, 2013 at 21:45

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