# Calculate "v^T A v" for a matrix of vectors v

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).

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! Aug 30, 2013 at 22:32

You can use the `numpy.einsum`:

``````np.einsum('ji,jk,ki->i',x,a,x)
``````

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

perfplot.show(
setup=setup,
kernels=[loop, einsum, dot],
n_range=[2**k for k in range(10)],
logx=True,
logy=True,
xlabel='n, k'
)
``````
• This is considerably slower for large dimension on modern processors due to its in ability to use a threaded BLAS. 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. 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). Aug 30, 2013 at 22:33
• 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) 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.

• 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. Aug 30, 2013 at 21:45