# optimal way of defining a numerically stable sigmoid function for a list in python

For a scalar variable `x`, we know how to write down a numerically stable sigmoid function in python:

``````def sigmoid(x):
if x >= 0:
return 1. / ( 1. + np.exp(-x) )
else:
return exp(x) / ( 1. + np.exp(x) )
``````

For a list of scalars, say `z = [x_1, x_2, x_3, ...]`, and suppose we don't know the sign of each `x_i` beforehand, we could generalize the above definition and try:

``````def sigmoid(z):
result = []
for x in z:
if x >= 0:
result.append(1. / ( 1. + np.exp(-x) ) )
else:
result.append( exp(x) / ( 1. + np.exp(x) ) )
return result
``````

This seems to work. However, I feel this is perhaps not the most pythonic way. How should I improve the definition in terms of 'cleanness'? Say, is there a way to use comprehension to shorten the function definition?

I'm sorry if this has been asked, because I cannot find similar questions on SO. Thank you very much for your time and help!

• It used to be as simple as `scipy.special.expit(x)`, but someone changed it back in 2016. – user2357112 supports Monica Aug 22 '18 at 23:37
• I'm not sure how important it is, though - I can find a few cases where the supposedly more stable version is about 1 ULP more accurate, but I can't find a solid analysis proving it's better, and the closest thing to a source I've found analyzes the behavior of overflow wrong, coming to the incorrect conclusion that the straightforward 1/(1+exp(-x)) implementation will return infinity for x=-100. – user2357112 supports Monica Aug 22 '18 at 23:44
• It seems like the superiority of the "stable" version may be a myth, or at most a tiny precision advantage. – user2357112 supports Monica Aug 22 '18 at 23:56
• @user2357112supportsMonica Infinity will be returned for ~`-710` with naive implementation (`numpy`, `double` precision) – Szymon Maszke Nov 6 '20 at 16:29

You are right, you can do better by using `np.where`, the numpy equivalent of `if`:

``````def sigmoid(x):
return np.where(x >= 0,
1 / (1 + np.exp(-x)),
np.exp(x) / (1 + np.exp(x)))
``````

This function takes a numpy array `x` and returns a numpy array, too:

``````data = np.arange(-5,5)
sigmoid(data)
#array([0.00669285, 0.01798621, 0.04742587, 0.11920292, 0.26894142,
#       0.5       , 0.73105858, 0.88079708, 0.95257413, 0.98201379])
``````
• Thanks for such a quick response. This is a lovely solution. May I ask is it possible to get rid of the element-wise for loop where we need to check the sign of x one at a time? – RandomWalker Aug 22 '18 at 23:40
• I do not follow you. There is no elementwise loop in the proposed solution. – DYZ Aug 22 '18 at 23:42
• Okay, I made a mistake when I passed a python list z to your definition, so an exception was raised. So I though I still need the for loop in the original definition. Passing np.array(z) works. I'll mark the question as solved. Thanks so much! – RandomWalker Aug 22 '18 at 23:45
• If you want to pass a list, just convert it to an array before passing (with `np.array(mylist)`). – DYZ Aug 22 '18 at 23:46
• seems like the `np.where` evaluates both branches and then chooses which one it needs, this results in misleading overflow warnings. something like `sigmoid(np.array(-300, np.float32))` – titus May 27 '20 at 8:18
``````def sigmoid(x):
"""
A numerically stable version of the logistic sigmoid function.
"""
z = np.zeros_like(x)
top = np.ones_like(x)
``````

This piece of code comes from assignment3 of cs231n, I don't really understand why we should calculate it in this way, but I know this may be the code that you are looking for. Hope to be helpful.

Another alternative to your code is the following:

``````def sigmoid(z):
return [(1. / (1. + np.exp(-x)) if x >= 0 else (np.exp(x) / (1. + np.exp(x))) for x in z]
``````
• There is really no point in using numpy functions and not using numpy vectorization. – DYZ Aug 22 '18 at 23:48
• This is a very nice and clean alternative. Thanks a lot! – RandomWalker Aug 22 '18 at 23:48
• @DYZ While I agree that your solution is shorter and more consequent, it is preferred to use list comprehensions instead of for loops. I will edit my answer so that everyone can see that this is an alternative to the code posted in the question, not to your solution. – F.G. Aug 22 '18 at 23:56

The accepted answer is correct but, as pointed out by this comment, it calculates both branches and is thus problematic.

Rather, you may want to use `np.piecewise()`. This is much faster, meaningful (`np.where` is not intended to define a piecewise function) and free of misleading warnings caused by entering into both branches.

## Benchmark

Source Code

``````import numpy as np
import time

N: int = int(1e+4)

np.random.seed(0)

x: np.ndarray = np.random.random((N, N))
x *= 1e+3

start: float = time.time()
y1 = np.where(x > 0, 1 / (1 + np.exp(-x)), np.exp(x) / (1 + np.exp(x)))
end: float = time.time()
print()
print(end - start)

start: float = time.time()
y2 = np.piecewise(x, [x > 0], [lambda i: 1 / (1 + np.exp(-i)), lambda i: np.exp(i) / (1 + np.exp(i))])
end: float = time.time()
print(end - start)

assert (np.array_equal(y1, y2))
``````

Result

`np.piecewise()` is silent and twice faster!

``````test.py:12: RuntimeWarning: overflow encountered in exp
y1 = np.where(x > 0, 1 / (1 + np.exp(-x)), np.exp(x) / (1 + np.exp(x)))
test.py:12: RuntimeWarning: invalid value encountered in true_divide
y1 = np.where(x > 0, 1 / (1 + np.exp(-x)), np.exp(x) / (1 + np.exp(x)))

6.32736349105835
3.138420343399048
``````
• See my answer for comparison and why your solution does not work for edge case (`np.array` is integer). – Szymon Maszke Nov 6 '20 at 16:25

I wrote one trick, I guess np.where or torch.where are implemented in the same manner to deal with binary conditions:

``````def sigmoid(x, max_v=1.0):
sign = (torch.sign(x) + 3)//3
x = torch.abs(x)
res = max_v/(1 + torch.exp(-x))
res = res * sign + (1 - sign) * (max_v - res)
return res
``````

Fully correct answer (no warnings) was provided by @hao peng but solution wasn't explained clearly. This would be too long for a comment, so I'll go for an answer.

Let's start with analysis of a few answers (pure `numpy` answers only):

This one is correct mathematically but still gives us a warning. Let's look at the code:

``````def sigmoid(x):
return np.where(
x >= 0, # condition
1 / (1 + np.exp(-x)), # For positive values
np.exp(x) / (1 + np.exp(x)) # For negative values
)
``````

As both branches are evaluated (they are arguments, they have to be), the first branch will give us a warning for negative values and the second for positive.

Although the warnings will be raised, results from overflows will not be incorporated, hence the result is correct.

### Downsides

• unnecessary evaluation of both branches (twice as many operations as needed)
• warnings are thrown

This one is almost correct, BUT will work only on floating point values, see below:

``````def sigmoid(x):
return np.piecewise(
x,
[x > 0],
[lambda i: 1 / (1 + np.exp(-i)), lambda i: np.exp(i) / (1 + np.exp(i))],
)

sigmoid(np.array([0.0, 1.0]))  # [0.5 0.73105858] correct
sigmoid(np.array([0, 1]))  # [0, 0] incorrect
``````

Why? Longer answer was provided by @mhawke in another thread, but the main point is:

It seems that piecewise() converts the return values to the same type as the input so, when an integer is input an integer conversion is performed on the result, which is then returned.

### Downsides

• no automatic casting due to strange behavior of piecewise function

Idea of stable sigmoid comes from the fact that: Both versions are equally efficient in terms of operations if coded correctly (one `exp` evaluation is enough). Now:

• `e^x` will overflow when `x` is positive
• `e^-x` will overflow when `x` is negative

Hence we have to branch when on `x` equal to zero. Use `numpy`'s masking we can transform only the part of array which is positive or negative with specific sigmoid implementations.

``````def _positive_sigmoid(x):
return 1 / (1 + np.exp(-x))

def _negative_sigmoid(x):
# Cache exp so you won't have to calculate it twice
exp = np.exp(x)
return exp / (exp + 1)

def sigmoid(x):
positive = x >= 0
# Boolean array inversion is faster than another comparison
negative = ~positive

# empty contains junk hence will be faster to allocate
# Zeros has to zero-out the array after allocation, no need for that
result = np.empty_like(x)
result[positive] = _positive_sigmoid(x[positive])
result[negative] = _negative_sigmoid(x[negative])

return result
``````

## Time measurements

Results (50 times case test from `ynn`):

289.5070939064026 #DYZ 222.49267292022705 #ynn 230.81086134910583 #this

Code below was used:

``````import time

import numpy as np

def _positive_sigmoid(x):
return 1 / (1 + np.exp(-x))

def _negative_sigmoid(x):
# Cache exp so you won't have to calculate it twice
exp = np.exp(x)
return exp / (exp + 1)

def sigmoid(x):
positive = x >= 0
# Boolean array inversion is faster than another comparison
negative = ~positive

# empty contains juke hence will be faster to allocate than zeros
result = np.empty_like(x)
result[positive] = _positive_sigmoid(x[positive])
result[negative] = _negative_sigmoid(x[negative])

return result

N = int(1e4)
x = np.random.uniform(size=(N, N))

start: float = time.time()
for _ in range(50):
y1 = np.where(x > 0, 1 / (1 + np.exp(-x)), np.exp(x) / (1 + np.exp(x)))
y1 += 1
end: float = time.time()
print(end - start)

start: float = time.time()
for _ in range(50):
y2 = np.piecewise(
x,
[x > 0],
[lambda i: 1 / (1 + np.exp(-i)), lambda i: np.exp(i) / (1 + np.exp(i))],
)
y2 += 1
end: float = time.time()
print(end - start)

start: float = time.time()
for _ in range(50):
y2 = sigmoid(x)
y2 += 1
end: float = time.time()
print(end - start)
``````