# Fastest way to compute entropy in Python

In my project I need to compute the entropy of 0-1 vectors many times. Here's my code:

``````def entropy(labels):
""" Computes entropy of 0-1 vector. """
n_labels = len(labels)

if n_labels <= 1:
return 0

counts = np.bincount(labels)
probs = counts[np.nonzero(counts)] / n_labels
n_classes = len(probs)

if n_classes <= 1:
return 0
return - np.sum(probs * np.log(probs)) / np.log(n_classes)
``````

Is there a faster way?

• What is a typical length of `labels`? Mar 16, 2013 at 14:09
• The length is not fixed.. Mar 16, 2013 at 14:12
• It would help with benchmarking to know typical values of `labels`. If `labels` is too short, a pure python implementation could actually be faster than using NumPy. Mar 16, 2013 at 14:13
• just to confirm, this question is for entropy of a discrete (binary) random variable? and not differential entropy of a continuous r.v.? Aug 4, 2020 at 8:37
• I don't know, how fast does your code run? This is opinion-based in its current format. Nov 3, 2021 at 19:26

@Sanjeet Gupta answer is good but could be condensed. This question is specifically asking about the "Fastest" way but I only see times on one answer so I'll post a comparison of using scipy and numpy to the original poster's entropy2 answer with slight alterations.

Four different approaches: (1) scipy/numpy, (2) numpy/math, (3) pandas/numpy, (4) numpy

``````import numpy as np
from scipy.stats import entropy
from math import log, e
import pandas as pd

import timeit

def entropy1(labels, base=None):
value,counts = np.unique(labels, return_counts=True)
return entropy(counts, base=base)

def entropy2(labels, base=None):
""" Computes entropy of label distribution. """

n_labels = len(labels)

if n_labels <= 1:
return 0

value,counts = np.unique(labels, return_counts=True)
probs = counts / n_labels
n_classes = np.count_nonzero(probs)

if n_classes <= 1:
return 0

ent = 0.

# Compute entropy
base = e if base is None else base
for i in probs:
ent -= i * log(i, base)

return ent

def entropy3(labels, base=None):
vc = pd.Series(labels).value_counts(normalize=True, sort=False)
base = e if base is None else base
return -(vc * np.log(vc)/np.log(base)).sum()

def entropy4(labels, base=None):
value,counts = np.unique(labels, return_counts=True)
norm_counts = counts / counts.sum()
base = e if base is None else base
return -(norm_counts * np.log(norm_counts)/np.log(base)).sum()

``````

Timeit operations:

``````repeat_number = 1000000

a = timeit.repeat(stmt='''entropy1(labels)''',
setup='''labels=[1,3,5,2,3,5,3,2,1,3,4,5];from __main__ import entropy1''',
repeat=3, number=repeat_number)

b = timeit.repeat(stmt='''entropy2(labels)''',
setup='''labels=[1,3,5,2,3,5,3,2,1,3,4,5];from __main__ import entropy2''',
repeat=3, number=repeat_number)

c = timeit.repeat(stmt='''entropy3(labels)''',
setup='''labels=[1,3,5,2,3,5,3,2,1,3,4,5];from __main__ import entropy3''',
repeat=3, number=repeat_number)

d = timeit.repeat(stmt='''entropy4(labels)''',
setup='''labels=[1,3,5,2,3,5,3,2,1,3,4,5];from __main__ import entropy4''',
repeat=3, number=repeat_number)
``````

Timeit results:

``````# for loop to print out results of timeit
for approach,timeit_results in zip(['scipy/numpy', 'numpy/math', 'pandas/numpy', 'numpy'], [a,b,c,d]):
print('Method: {}, Avg.: {:.6f}'.format(approach, np.array(timeit_results).mean()))

Method: scipy/numpy, Avg.: 63.315312
Method: numpy/math, Avg.: 49.256894
Method: pandas/numpy, Avg.: 884.644023
Method: numpy, Avg.: 60.026938
``````

Winner: numpy/math (`entropy2`)

It's also worth noting that the `entropy2` function above can handle numeric AND text data. ex: `entropy2(list('abcdefabacdebcab'))`. The original poster's answer is from 2013 and had a specific use-case for binning ints but it won't work for text.

• You're using such a small array that your tests are basically useless. You're really just measuring call overhead for the various interfaces. Jul 8, 2018 at 4:03
• Using this code I just got the timing for my answer ("An answer that doesn't rely on numpy, either...") as well -- and it's `Method: eta, Avg.: 10.461799`. As someone suggested, I wonder if you're actually testing call overhead here. Sep 17, 2018 at 11:40
• It's better to take the minimum of the timeit results, instead of the mean. See the "note" under the repeat function of the timeit module. Dec 19, 2019 at 0:06
• vectorizer operations may be preferred for large inputs. The 'for' loop in option 2 may not be a good option in such cases. In my view option 1 may be preferable. Sep 20, 2021 at 14:15

With the data as a `pd.Series` and `scipy.stats`, calculating the entropy of a given quantity is pretty straightforward:

``````import pandas as pd
import scipy.stats

def ent(data):
"""Calculates entropy of the passed `pd.Series`
"""
p_data = data.value_counts()           # counts occurrence of each value
entropy = scipy.stats.entropy(p_data)  # get entropy from counts
return entropy
``````

Note: `scipy.stats` will normalize the provided data, so this doesn't need to be done explicitly, i.e. passing an array of counts works fine.

• The `value_counts()` method just counts. The probabily `p_data` wouldn't be `p_data = data.value_counts()/sum(data.value_counts().values)` So you will have the count for each class divided by the total amount of data, then you have the probability of each class. Mar 28, 2022 at 14:03

An answer that doesn't rely on numpy, either:

``````import math
from collections import Counter

def eta(data, unit='natural'):
base = {
'shannon' : 2.,
'natural' : math.exp(1),
'hartley' : 10.
}

if len(data) <= 1:
return 0

counts = Counter()

for d in data:
counts[d] += 1

ent = 0

probs = [float(c) / len(data) for c in counts.values()]
for p in probs:
if p > 0.:
ent -= p * math.log(p, base[unit])

return ent
``````

This will accept any datatype you could throw at it:

``````>>> eta(['mary', 'had', 'a', 'little', 'lamb'])
1.6094379124341005

>>> eta([c for c in "mary had a little lamb"])
2.311097886212714
``````

The answer provided by @Jarad suggested timings as well. To that end:

``````repeat_number = 1000000
e = timeit.repeat(
stmt='''eta(labels)''',
setup='''labels=[1,3,5,2,3,5,3,2,1,3,4,5];from __main__ import eta''',
repeat=3,
number=repeat_number)
``````

Timeit results: (I believe this is ~4x faster than the best numpy approach)

``````print('Method: {}, Avg.: {:.6f}'.format("eta", np.array(e).mean()))

Method: eta, Avg.: 10.461799
``````
• why do you need probs = [p for p in probs if p > 0.]?
Aug 20, 2018 at 5:41
• Since I'm doing that test five lines later I suspect I don't need it at all :) Edited. Sep 17, 2018 at 11:28
• plus one for no new dependencies Apr 9, 2020 at 15:36
• Can you do counts = Counter(data) instead of looping over the characters of data? Oct 23, 2020 at 4:22

Following the suggestion from unutbu I create a pure python implementation.

``````def entropy2(labels):
""" Computes entropy of label distribution. """
n_labels = len(labels)

if n_labels <= 1:
return 0

counts = np.bincount(labels)
probs = counts / n_labels
n_classes = np.count_nonzero(probs)

if n_classes <= 1:
return 0

ent = 0.

# Compute standard entropy.
for i in probs:
ent -= i * log(i, base=n_classes)

return ent
``````

The point I was missing was that labels is a large array, however probs is 3 or 4 elements long. Using pure python my application now is twice as fast.

• Should 'base' be set to the number of classes? I thought there the natural log was the standard (and what you used in your original question.) Jun 17, 2016 at 21:22

Here is my approach:

``````labels = [0, 0, 1, 1]

from collections import Counter
from scipy import stats

stats.entropy(list(Counter(labels).values()), base=2)
``````
• This seems to work for my image slices but I actually need the probability of pixel values in the slice from 0 to 255. Nov 12, 2019 at 8:52

Uniformly distributed data (high entropy):

``````s=range(0,256)
``````

Shannon entropy calculation step by step:

``````import collections
import math

# calculate probability for each byte as number of occurrences / array length
probabilities = [n_x/len(s) for x,n_x in collections.Counter(s).items()]
# [0.00390625, 0.00390625, 0.00390625, ...]

# calculate per-character entropy fractions
e_x = [-p_x*math.log(p_x,2) for p_x in probabilities]
# [0.03125, 0.03125, 0.03125, ...]

# sum fractions to obtain Shannon entropy
entropy = sum(e_x)
>>> entropy
8.0
``````

One-liner (assuming `import collections`):

``````def H(s): return sum([-p_x*math.log(p_x,2) for p_x in [n_x/len(s) for x,n_x in collections.Counter(s).items()]])
``````

A proper function:

``````import collections
import math

def H(s):
probabilities = [n_x/len(s) for x,n_x in collections.Counter(s).items()]
e_x = [-p_x*math.log(p_x,2) for p_x in probabilities]
return sum(e_x)
``````

Test cases - English text taken from CyberChef entropy estimator:

``````>>> H(range(0,256))
8.0
>>> H(range(0,64))
6.0
>>> H(range(0,128))
7.0
>>> H([0,1])
1.0
>>> H('Standard English text usually falls somewhere between 3.5 and 5')
4.228788210509104
``````
• This makes it very clear regarding ability to calculate entropy over a specified range of values. I need to apply this method to the 8-connected area around a pixel and their grayscale values. Wondering if I could do with a built-in method as well. Nov 12, 2019 at 8:09

My favorite function for entropy is the following:

``````def entropy(labels):
prob_dict = {x:labels.count(x)/len(labels) for x in labels}
probs = np.array(list(prob_dict.values()))

return - probs.dot(np.log2(probs))
``````

I am still looking for a nicer way to avoid the dict -> values -> list -> np.array conversion. Will comment again if I found it.

• nice, use collections.Counter would be better. May 20, 2017 at 16:22
• In python2, `labels.count(x)/len(labels)` should be `labels.count(x)/float(len(labels))` Feb 10, 2019 at 10:26

This method extends the other solutions by allowing for binning. For example, `bin=None` (default) won't bin `x` and will compute an empirical probability for each element of `x`, while `bin=256` chunks `x` into 256 bins before computing the empirical probabilities.

``````import numpy as np

def entropy(x, bins=None):
N   = x.shape
if bins is None:
counts = np.bincount(x)
else:
counts = np.histogram(x, bins=bins) # 0th idx is counts
p   = counts[np.nonzero(counts)]/N # avoids log(0)
H   = -np.dot( p, np.log2(p) )
return H
``````

This is the fastest Python implementation I've found so far:

``````import numpy as np

def entropy(labels):
ps = np.bincount(labels) / len(labels)
return -np.sum([p * np.log2(p) for p in ps if p > 0])
``````
``````from collections import Counter
from scipy import stats

labels = [0.9, 0.09, 0.1]
stats.entropy(list(Counter(labels).keys()), base=2)
``````
• While this may answer the question, code only answers are generally regarded as lo-quality. Providing some more description and context on why will improve the quality of this answer. Thanks. Jun 28, 2019 at 23:42

BiEntropy wont be the fastest way of computing entropy, but it is rigorous and builds upon Shannon Entropy in a well defined way. It has been tested in various fields including image related applications. It is implemented in Python on Github.

Bit late for the party, but I stumbled at this and all answers seems to rely on Kullback–Leibler divergence, which has no upper bound, and hence, doesn't fit my needs.

Here I have an approximation (the `TODO!`could be improved) of an entropy function that goes from [0,1].

It calculates the biass of a single column.

``````class Pandas_Dataframe_helper:
#some other methods here...
@staticmethod
def column_biass(df_column):
df_column_as_list           =   list(df_column)
N                           =   len(df_column_as_list)
values,counts               =   np.unique(df_column_as_list, return_counts=True)
#generate synth list (TODO! what if not even number? Minimum Comun Multiple of(num_different_labels,[x for x in counts]))
num_different_labels        =   len(values)
num_items_per_label         =   N // num_different_labels
synthetic_list              =   []
for current_value in values:
synthetic_list.extend([current_value] * num_items_per_label)
#TODO! aproximacion
if(len(synthetic_list) != len(df_column_as_list)):
synthetic_list.extend([current_value] * (len(df_column_as_list) - len(synthetic_list)))
#now, extrapolate differences between sorted-input-list and synsthetic_list
df_column_as_list_sorted    =   sorted(df_column_as_list)
counter_unmatches           =   0
for i in range(0,N):
if(df_column_as_list_sorted[i] != synthetic_list[i]):
counter_unmatches   +=  1
#upper_bound = g(N,num_different_labels)
#((K-1)M)-1 K==num_different_labels , M==num theorically perfect distribution's items per label
upper_bound                 =   ((num_different_labels-1)*num_items_per_label)-1
return counter_unmatches/upper_bound
#---------------------------------------------------------------------------------------------------------------------

``````

The above answer is good, but if you need a version that can operate along different axes, here's a working implementation.

``````def entropy(A, axis=None):
"""Computes the Shannon entropy of the elements of A. Assumes A is
an array-like of nonnegative ints whose max value is approximately
the number of unique values present.

>>> a = [0, 1]
>>> entropy(a)
1.0
>>> A = np.c_[a, a]
>>> entropy(A)
1.0
>>> A                   # doctest: +NORMALIZE_WHITESPACE
array([[0, 0], [1, 1]])
>>> entropy(A, axis=0)  # doctest: +NORMALIZE_WHITESPACE
array([ 1., 1.])
>>> entropy(A, axis=1)  # doctest: +NORMALIZE_WHITESPACE
array([[ 0.], [ 0.]])
>>> entropy([0, 0, 0])
0.0
>>> entropy([])
0.0
>>> entropy()
0.0
"""
if A is None or len(A) < 2:
return 0.

A = np.asarray(A)

if axis is None:
A = A.flatten()
counts = np.bincount(A) # needs small, non-negative ints
counts = counts[counts > 0]
if len(counts) == 1:
return 0. # avoid returning -0.0 to prevent weird doctests
probs = counts / float(A.size)
return -np.sum(probs * np.log2(probs))
elif axis == 0:
entropies = map(lambda col: entropy(col), A.T)
return np.array(entropies)
elif axis == 1:
entropies = map(lambda row: entropy(row), A)
return np.array(entropies).reshape((-1, 1))
else:
raise ValueError("unsupported axis: {}".format(axis))
``````
``````def entropy(base, prob_a, prob_b ):
import math
base=2
x=prob_a
y=prob_b
expression =-((x*math.log(x,base)+(y*math.log(y,base))))
return [expression]
``````
• When you answer with code, you should write some explanation. Dec 29, 2019 at 0:12
• In the question the argument is a label list Apr 5, 2021 at 23:31