If I have numpy arrays A and B, then I can compute the trace of their matrix product with:

tr = numpy.linalg.trace(A.dot(B))

However, the matrix multiplication A.dot(B) unnecessarily computes all of the off-diagonal entries in the matrix product, when only the diagonal elements are used in the trace. Instead, I could do something like:

tr = 0.0
for i in range(n):
    tr += A[i, :].dot(B[:, i])

but this performs the loop in Python code and isn't as obvious as numpy.linalg.trace.

Is there a better way to compute the trace of a matrix product of numpy arrays? What is the fastest or most idiomatic way to do this?


You can improve on @Bill's solution by reducing intermediate storage to the diagonal elements only:

from numpy.core.umath_tests import inner1d

m, n = 1000, 500

a = np.random.rand(m, n)
b = np.random.rand(n, m)

# They all should give the same result
print np.trace(a.dot(b))
print np.sum(a*b.T)
print np.sum(inner1d(a, b.T))

%timeit np.trace(a.dot(b))
10 loops, best of 3: 34.7 ms per loop

%timeit np.sum(a*b.T)
100 loops, best of 3: 4.85 ms per loop

%timeit np.sum(inner1d(a, b.T))
1000 loops, best of 3: 1.83 ms per loop

Another option is to use np.einsum and have no explicit intermediate storage at all:

# Will print the same as the others:
print np.einsum('ij,ji->', a, b)

On my system it runs slightly slower than using inner1d, but it may not hold for all systems, see this question:

%timeit np.einsum('ij,ji->', a, b)
100 loops, best of 3: 1.91 ms per loop
  • On my machine, the inner1d and einsum approaches are basically indistinguishable in speed. – amcnabb Sep 17 '13 at 16:48
  • 1
    One would think that np.einsum would have a slight edge, because it doesn't have to store all the diagonal elements before adding them, it keeps a running sum. And it uses SIMD instructions, so you should get a factor of 2 or 4 improvement over inner1d. But they perform identically on my system as well, even for larger data. – Jaime Sep 17 '13 at 16:51
  • By the way, is umath_tests a stable public API? The name makes it sound private, and it seems to be less documented than the other parts of numpy. – amcnabb Sep 17 '13 at 16:52
  • @amcnabb Thats interesting- what version of numpy are you using? Examining the source code it looks like inner1d is a C++ definition that is written to make use of SSE. See here. Could help answer the einsum question. – Daniel Sep 17 '13 at 16:54
  • 1
    @amcnabb In numpy 1.8 inner1d is going to be included in numpy.linalg._umath_linalg, not sure if it will stay in numpy.core.umath_tests. It may move around, but I think there is a clear intention to keep it and expose it moer and more. – Jaime Sep 17 '13 at 17:43

From wikipedia you can calculate the trace using the hammard product (element-wise multiplication):

# Tr(A.B)
tr = (A*B.T).sum()

I think this is less computation than doing numpy.trace(A.dot(B)).


Ran some timers. This way is much faster than using numpy.trace.

In [37]: timeit("np.trace(A.dot(B))", setup="""import numpy as np;
A, B = np.random.rand(1000,1000), np.random.rand(1000,1000)""", number=100)
Out[38]: 8.6434469223022461

In [39]: timeit("(A*B.T).sum()", setup="""import numpy as np;
A, B = np.random.rand(1000,1000), np.random.rand(1000,1000)""", number=100)
Out[40]: 0.5516049861907959
  • This seems to be faster than numpy.trace even if the matrices aren't symmetrical (e.g. if A is 1000x100 and B is 100x1000, or vice versa). – amcnabb Sep 17 '13 at 16:27
  • 4
    You might want to mention that A and B must be ndarrays exclusively so its not confusing. Also it should be noted that the timings are heavily influenced by what kind of BLAS your numpy is linked to. For additional speed consider using the expression np.einsum('ij,ji->',A,B). – Daniel Sep 17 '13 at 16:30
  • 1
    @Ophion Had included that in my answer before reading this... We may have another case of the mysterious slowness of np.einsum on my system... – Jaime Sep 17 '13 at 16:45

Note that one slight variant is to take the dot product of the vectorized matrices. In python, vectorization is done using .flatten('F'). It's slightly slower than taking the sum of the Hadamard product, on my computer, so it's a worse solution than wflynny's , but I think it's kind of interesting, since it can be more intuitive, in some situations, in my opinion. For example, personally I find that for the matrix normal distribution, the vectorized solution is easier for me to understand.

Speed comparison, on my system:

import numpy as np
import time

N = 1000

A = np.random.randn(N, N)
B = np.random.randn(N, N)

tart = time.time()
for i in range(10):
    C = np.trace(A.dot(B))
print(time.time() - start, C)

start = time.time()
for i in range(10):
    C = A.flatten('F').dot(B.T.flatten('F'))
print(time.time() - start, C)

start = time.time()
for i in range(10):
    C = (A.T * B).sum()
print(time.time() - start, C)

start = time.time()
for i in range(10):
    C = (A * B.T).sum()
print(time.time() - start, C)


6.246593236923218 -629.370798672
0.06539678573608398 -629.370798672
0.057890892028808594 -629.370798672
0.05709719657897949 -629.370798672

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