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?
@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.
Method: eta, Avg.: 10.461799. As someone suggested, I wonder if you're actually testing call overhead here.
Sep 17, 2018 at 11:40
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.
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.
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
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.
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)
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
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.
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[0]
if bins is None:
counts = np.bincount(x)
else:
counts = np.histogram(x, bins=bins)[0] # 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)
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
#---------------------------------------------------------------------------------------------------------------------
Complete code at https://github.com/glezo1/pcommonlibs/blob/master/com/glezo/pandas_dataframe_helper/Pandas_Dataframe_Helper.py
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([5])
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]
labels?labels. Iflabelsis too short, a pure python implementation could actually be faster than using NumPy.