Is there a numerically stable way to compute softmax function below? I am getting values that becomes Nans in Neural network code.
np.exp(x)/np.sum(np.exp(y))
Is there a numerically stable way to compute softmax function below? I am getting values that becomes Nans in Neural network code.
np.exp(x)/np.sum(np.exp(y))
The softmax exp(x)/sum(exp(x)) is actually numerically well-behaved. It has only positive terms, so we needn't worry about loss of significance, and the denominator is at least as large as the numerator, so the result is guaranteed to fall between 0 and 1.
The only accident that might happen is over- or under-flow in the exponentials. Overflow of a single or underflow of all elements of x will render the output more or less useless.
But it is easy to guard against that by using the identity softmax(x) = softmax(x + c) which holds for any scalar c: Subtracting max(x) from x leaves a vector that has only non-positive entries, ruling out overflow and at least one element that is zero ruling out a vanishing denominator (underflow in some but not all entries is harmless).
Footnote: theoretically, catastrophic accidents in the sum are possible, but you'd need a ridiculous number of terms. For example, even using 16 bit floats which can only resolve 3 decimals---compared to 15 decimals of a "normal" 64 bit float---we'd need between 2^1431 (~6 x 10^431) and 2^1432 to get a sum that is off by a factor of two.
Softmax function is prone to two issues: overflow and underflow
Overflow: It occurs when very large numbers are approximated as infinity
Underflow: It occurs when very small numbers (near zero in the number line) are approximated (i.e. rounded to) as zero
To combat these issues when doing softmax computation, a common trick is to shift the input vector by subtracting the maximum element in it from all elements. For the input vector x
, define z
such that:
z = x-max(x)
And then take the softmax of the new (stable) vector z
Example:
def stable_softmax(x):
z = x - max(x)
numerator = np.exp(z)
denominator = np.sum(numerator)
softmax = numerator/denominator
return softmax
# input vector
In [267]: vec = np.array([1, 2, 3, 4, 5])
In [268]: stable_softmax(vec)
Out[268]: array([ 0.01165623, 0.03168492, 0.08612854, 0.23412166, 0.63640865])
# input vector with really large number, prone to overflow issue
In [269]: vec = np.array([12345, 67890, 99999999])
In [270]: stable_softmax(vec)
Out[270]: array([ 0., 0., 1.])
In the above case, we safely avoided the overflow problem by using stable_softmax()
For more details, see chapter Numerical Computation in deep learning book.
Extending @kmario23's answer to support 1 or 2 dimensional numpy arrays or lists. 2D tensors (assuming the first dimension is the batch dimension) are common if you're passing a batch of results through softmax:
import numpy as np
def stable_softmax(x):
z = x - np.max(x, axis=-1, keepdims=True)
numerator = np.exp(z)
denominator = np.sum(numerator, axis=-1, keepdims=True)
softmax = numerator / denominator
return softmax
test1 = np.array([12345, 67890, 99999999]) # 1D numpy
test2 = np.array([[12345, 67890, 99999999], # 2D numpy
[123, 678, 88888888]]) #
test3 = [12345, 67890, 999999999] # 1D list
test4 = [[12345, 67890, 999999999]] # 2D list
print(stable_softmax(test1))
print(stable_softmax(test2))
print(stable_softmax(test3))
print(stable_softmax(test4))
[0. 0. 1.]
[[0. 0. 1.]
[0. 0. 1.]]
[0. 0. 1.]
[[0. 0. 1.]]
np.seterr(all='raise')
will complain about underflows for large values even though the function works correctly. This is indeed the best solution.
Commented
May 4, 2020 at 16:33
There is nothing wrong with calculating the softmax function as it is in your case. The problem seems to come from exploding gradient or this sort of issues with your training methods. Focus on those matters with either "clipping values" or "choosing the right initial distribution of weights".
softmax(800)
with it.
Commented
Mar 5, 2017 at 0:39