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[0], b.shape[1]))
for n in range(b.shape[1]):
# 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],1)) + repeat(b.T, a.shape[0], axis=0)).reshape(b.shape[1],a.shape[0],a.shape[1]), 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  [1] a = np.log(np.random.rand(1000,2000))

In  [2] b = np.log(np.random.rand(2000,1500))

In  [3] x = logdot(a, b)

In  [4] y = logdot_old(a, b) # this takes a while

In  [5] np.any(np.abs(x-y) > 1e-14)
Out [5] False

In  [6] %timeit logdot_old(a, b)
1 loops, best of 3: 1min 18s per loop

In  [6] %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]]
``````