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Normally I would invert an array of 3x3 matrices in a for loop like in the example below. Unfortunately for loops are slow. Is there a faster, more efficient way to do this?

import numpy as np
A = np.random.rand(3,3,100)
Ainv = np.zeros_like(A)
for i in range(100):
    Ainv[:,:,i] = np.linalg.inv(A[:,:,i])
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Also, have you had a look here?… –  Robert Harvey Aug 15 '12 at 15:20
Are for loops really that slow in Python? –  Robert Harvey Aug 15 '12 at 15:24
Inverting a 3x3 matrix using inv takes about 51.8 us for me. for i in range(100): pass takes 2.89 us, so the loop overhead for each inv is totally negligible. The time to compute a slice is about 1.2 us. I don't think for loop speed is a factor here, and only timeit data will convince me otherwise. –  DSM Aug 15 '12 at 15:30
@DSM -- I think your comment is about as good of an answer as we're gonna get on this one. I think you should put that as an answer (along with an explanation about how timeit is your friend, and you should only really worry about optimizing your innermost loop when you have nested loops, etc, etc). –  mgilson Aug 15 '12 at 15:38

2 Answers 2

up vote 7 down vote accepted

It turns out that you're getting burned two levels down in the numpy.linalg code. If you look at numpy.linalg.inv, you can see it's just a call to numpy.linalg.solve(A, inv(A.shape[0]). This has the effect of recreating the identity matrix in each iteration of your for loop. Since all your arrays are the same size, that's a waste of time. Skipping this step by pre-allocating the identity matrix shaves ~20% off the time (fast_inverse). My testing suggests that pre-allocating the array or allocating it from a list of results doesn't make much difference.

Look one level deeper and you find the call to the lapack routine, but it's wrapped in several sanity checks. If you strip all these out and just call lapack in your for loop (since you already know the dimensions of your matrix and maybe know that it's real, not complex), things run MUCH faster (Note that I've made my array larger):

import numpy as np
A = np.random.rand(1000,3,3)
def slow_inverse(A): 
    Ainv = np.zeros_like(A)

    for i in range(A.shape[0]):
        Ainv[i] = np.linalg.inv(A[i])
    return Ainv

def fast_inverse(A):
    identity = np.identity(A.shape[2], dtype=A.dtype)
    Ainv = np.zeros_like(A)

    for i in range(A.shape[0]):
        Ainv[i] = np.linalg.solve(A[i], identity)
    return Ainv

def fast_inverse2(A):
    identity = np.identity(A.shape[2], dtype=A.dtype)

    return array([np.linalg.solve(x, identity) for x in A])

from numpy.linalg import lapack_lite
lapack_routine = lapack_lite.dgesv
# Looking one step deeper, we see that solve performs many sanity checks.  
# Stripping these, we have:
def faster_inverse(A):
    b = np.identity(A.shape[2], dtype=A.dtype)

    n_eq = A.shape[1]
    n_rhs = A.shape[2]
    pivots = zeros(n_eq, np.intc)
    identity  = np.eye(n_eq)
    def lapack_inverse(a):
        b = np.copy(identity)
        pivots = zeros(n_eq, np.intc)
        results = lapack_lite.dgesv(n_eq, n_rhs, a, n_eq, pivots, b, n_eq, 0)
        if results['info'] > 0:
            raise LinAlgError('Singular matrix')
        return b

    return array([lapack_inverse(a) for a in A])

%timeit -n 20 aI11 = slow_inverse(A)
%timeit -n 20 aI12 = fast_inverse(A)
%timeit -n 20 aI13 = fast_inverse2(A)
%timeit -n 20 aI14 = faster_inverse(A)

The results are impressive:

20 loops, best of 3: 45.1 ms per loop
20 loops, best of 3: 38.1 ms per loop
20 loops, best of 3: 38.9 ms per loop
20 loops, best of 3: 13.8 ms per loop

EDIT: I didn't look closely enough at what gets returned in solve. It turns out that the 'b' matrix is overwritten and contains the result in the end. This code now gives consistent results.

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Does the numpy array have to be contiguous and in a specific order ('C' or 'F') ? –  Juh_ Aug 17 '12 at 12:44
Very nice. Could you do the same with eig :-) –  Juh_ Aug 17 '12 at 12:44
Thank you very much for your answer. –  katrasnikj Aug 17 '12 at 17:51
@Juh_: I believe the order of the array matters. Use the default. I recently implemented something very similar where I wanted the minimum eigenvalue. Rather than computing it on each array, I looked up the analytical solution for a 2x2 and coded that up. It sped things up hundreds to thousands of times. –  Carl F. Aug 17 '12 at 23:17
If A is positive definitive, instead of solving for A,I isn't it faster to decompose (Cholesky) A to LL* then solve L,I with solve_triangular or directly with linalg.lapack.clapack.dtrtri, then answer is one matrix multiply away? –  dashesy Apr 22 at 18:25

For loops are indeed not necessarily much slower than the alternatives and also in this case, it will not help you much. But here is a suggestion:

import numpy as np
A = np.random.rand(100,3,3) #this is to makes it 
                            #possible to index 
                            #the matrices as A[i]
Ainv = np.array(map(np.linalg.inv, A))

Timing this solution vs. your solution yields a small but noticeable difference:

# The for loop:
100 loops, best of 3: 6.38 ms per loop
# The map:
100 loops, best of 3: 5.81 ms per loop

I tried to use the numpy routine 'vectorize' with the hope of creating an even cleaner solution, but I'll have to take a second look into that. The change of ordering in the array A is probably the most significant change, since it utilises the fact that numpy arrays are ordered column-wise and therefor a linear readout of the data is ever so slightly faster this way.

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