numerically stable way to multiply log probability matrices in numpy

I need to take the matrix product of two NumPy matrices (or other 2d arrays) containing log probabilities. The naive way np.log(np.dot(np.exp(a), np.exp(b))) is not preferred for obvious reasons.

Using

from scipy.misc import logsumexp
res = np.zeros((a.shape, b.shape))
for n in range(b.shape):
# broadcast b[:,n] over rows of a, sum columns
res[:, n] = logsumexp(a + b[:, n].T, axis=1)

works but runs about 100 times slower than np.log(np.dot(np.exp(a), np.exp(b)))

Using

logsumexp((tile(a, (b.shape,1)) + repeat(b.T, a.shape, axis=0)).reshape(b.shape,a.shape,a.shape), 2).T

or other combinations of tile and reshape also work but run even slower than the loop above due to the prohibitively large amounts of memory required for realistically sized input matrices.

I am currently considering writing a NumPy extension in C to compute this, but of course I'd rather avoid that. Is there an established way to do this, or does anybody know of a less memory intensive way of performing this computation?

EDIT: Thanks to larsmans for this solution (see below for derivation):

def logdot(a, b):
max_a, max_b = np.max(a), np.max(b)
exp_a, exp_b = a - max_a, b - max_b
np.exp(exp_a, out=exp_a)
np.exp(exp_b, out=exp_b)
c = np.dot(exp_a, exp_b)
np.log(c, out=c)
c += max_a + max_b
return c

A quick comparison of this method to the method posted above (logdot_old) using iPython's magic %timeit function yields the following:

In   a = np.log(np.random.rand(1000,2000))

In   b = np.log(np.random.rand(2000,1500))

In   x = logdot(a, b)

In   y = logdot_old(a, b) # this takes a while

In   np.any(np.abs(x-y) > 1e-14)
Out  False

In   %timeit logdot_old(a, b)
1 loops, best of 3: 1min 18s per loop

In   %timeit logdot(a, b)
1 loops, best of 3: 264 ms per loop

Obviously larsmans' method obliterates mine!

• if you already know C, you could use scipy.weave.blitz to incorporate a few lines of C in the rest of your python code – usethedeathstar May 13 '14 at 13:38
• Alas, scipy.weave is not available for python3 – mart May 13 '14 at 14:18
• In your example I don't think that scipy.misc.logsumexp is doing what you think it is - according to the docs the b= parameter is actually a scaling factor for exp(a), i.e. np.log(np.sum(b*np.exp(a))). – ali_m May 13 '14 at 18:28
• @mart: why are you interpreting your weights as probabilities? – Neil G May 13 '14 at 22:24
• Weave is in a deprecation cycle. Any new code should be using Cython instead. – Davidmh May 13 '14 at 23:08

logsumexp works by evaluating the right-hand side of the equation

log(∑ exp[a]) = max(a) + log(∑ exp[a - max(a)])

I.e., it pulls out the max before starting to sum, to prevent overflow in exp. The same can be applied before doing vector dot products:

log(exp[a] ⋅ exp[b])
= log(∑ exp[a] × exp[b])
= log(∑ exp[a + b])
= max(a + b) + log(∑ exp[a + b - max(a + b)])     { this is logsumexp(a + b) }

but by taking a different turn in the derivation, we obtain

log(∑ exp[a] × exp[b])
= max(a) + max(b) + log(∑ exp[a - max(a)] × exp[b - max(b)])
= max(a) + max(b) + log(exp[a - max(a)] ⋅ exp[b - max(b)])

The final form has a vector dot product in its innards. It also extends readily to matrix multiplication, so we get the algorithm

def logdotexp(A, B):
max_A = np.max(A)
max_B = np.max(B)
C = np.dot(np.exp(A - max_A), np.exp(B - max_B))
np.log(C, out=C)
C += max_A + max_B
return C

This creates two A-sized temporaries and two B-sized ones, but one of each can be eliminated by

exp_A = A - max_A
np.exp(exp_A, out=exp_A)

and similarly for B. (If the input matrices may be modified by the function, all the temporaries can be eliminated.)

• Thanks! I'll try if this gives the performance I was hoping for. – mart Jun 5 '14 at 15:36
• This is less stable than the original slower solution. Consider logdotexp([[0,0],[0,0]], [[-1000,0], [-1000,0]]). – identity-m Apr 9 '15 at 3:51
• @identity-m you're right. This method does not control stability for all elements. See my answer which also handles the counterexample you provided. – Hassan Oct 21 '18 at 14:10

You are accessing columns of res and b, which has poor locality of reference. One thing to try is to store these in column-major order.

• I noticed this too, but for larger arrays (size > 1000) the logsumexp operation dominates. – user545424 May 13 '14 at 22:26

Suppose A.shape==(n,r) and B.shape==(r,m). In computing the matrix product C=A*B, there are actually n*m summations. To have stable results when you're working in log-space, You need the logsumexp trick in each of these summations. Fortunately, using numpy broadcasting that's quite easy to control stability of rows and columns of A and B separately.

Here is the code:

def logdotexp(A, B):
max_A = np.max(A,1,keepdims=True)
max_B = np.max(B,0,keepdims=True)
C = np.dot(np.exp(A - max_A), np.exp(B - max_B))
np.log(C, out=C)
C += max_A + max_B
return C

Note:

The reasoning behind this is similar to the FredFoo's answer, but he used a single maximum value for each matrix. Since he did not consider every n*m summations, some elements of the final matrix might still be unstable as mentioned in one of the comments.

Comparing with the currently accepted answer using @identity-m counter example:

def logdotexp_less_stable(A, B):
max_A = np.max(A)
max_B = np.max(B)
C = np.dot(np.exp(A - max_A), np.exp(B - max_B))
np.log(C, out=C)
C += max_A + max_B
return C

print('old method:')
print(logdotexp_less_stable([[0,0],[0,0]], [[-1000,0], [-1000,0]]))
print('new method:')
print(logdotexp([[0,0],[0,0]], [[-1000,0], [-1000,0]]))

which prints

old method:
[[      -inf 0.69314718]
[      -inf 0.69314718]]
new method:
[[-9.99306853e+02  6.93147181e-01]
[-9.99306853e+02  6.93147181e-01]]