Given a set
{0, 1, 2, 3}
How can I produce the subsets:
[set(),
{0},
{1},
{2},
{3},
{0, 1},
{0, 2},
{0, 3},
{1, 2},
{1, 3},
{2, 3},
{0, 1, 2},
{0, 1, 3},
{0, 2, 3},
{1, 2, 3},
{0, 1, 2, 3}]
Given a set
{0, 1, 2, 3}
How can I produce the subsets:
[set(),
{0},
{1},
{2},
{3},
{0, 1},
{0, 2},
{0, 3},
{1, 2},
{1, 3},
{2, 3},
{0, 1, 2},
{0, 1, 3},
{0, 2, 3},
{1, 2, 3},
{0, 1, 2, 3}]
The Python itertools
page has exactly a powerset
recipe for this:
from itertools import chain, combinations
def powerset(iterable):
"powerset([1,2,3]) --> () (1,) (2,) (3,) (1,2) (1,3) (2,3) (1,2,3)"
s = list(iterable)
return chain.from_iterable(combinations(s, r) for r in range(len(s)+1))
Output:
>>> list(powerset("abcd"))
[(), ('a',), ('b',), ('c',), ('d',), ('a', 'b'), ('a', 'c'), ('a', 'd'), ('b', 'c'), ('b', 'd'), ('c', 'd'), ('a', 'b', 'c'), ('a', 'b', 'd'), ('a', 'c', 'd'), ('b', 'c', 'd'), ('a', 'b', 'c', 'd')]
If you don't like that empty tuple at the beginning, you can just change the range
statement to range(1, len(s)+1)
to avoid a 0-length combination.
__len__
implemented; try out powerset((n for n in range(3)))
without the list wrapping.
– hoefling
Mar 21 '18 at 22:14
powerset(range(3))
would work fine even without s = list(iterable)
.
– user2357112 supports Monica
Mar 27 at 9:10
Here is more code for a powerset. This is written from scratch:
>>> def powerset(s):
... x = len(s)
... for i in range(1 << x):
... print [s[j] for j in range(x) if (i & (1 << j))]
...
>>> powerset([4,5,6])
[]
[4]
[5]
[4, 5]
[6]
[4, 6]
[5, 6]
[4, 5, 6]
Mark Rushakoff's comment is applicable here: "If you don't like that empty tuple at the beginning, on."you can just change the range statement to range(1, len(s)+1) to avoid a 0-length combination", except in my case you change for i in range(1 << x)
to for i in range(1, 1 << x)
.
Returning to this years later, I'd now write it like this:
def powerset(s):
x = len(s)
masks = [1 << i for i in range(x)]
for i in range(1 << x):
yield [ss for mask, ss in zip(masks, s) if i & mask]
And then the test code would look like this, say:
print(list(powerset([4, 5, 6])))
Using yield
means that you do not need to calculate all results in a single piece of memory. Precalculating the masks outside the main loop is assumed to be a worthwhile optimization.
If you're looking for a quick answer, I just searched "python power set" on google and came up with this: Python Power Set Generator
Here's a copy-paste from the code in that page:
def powerset(seq):
"""
Returns all the subsets of this set. This is a generator.
"""
if len(seq) <= 1:
yield seq
yield []
else:
for item in powerset(seq[1:]):
yield [seq[0]]+item
yield item
This can be used like this:
l = [1, 2, 3, 4]
r = [x for x in powerset(l)]
Now r is a list of all the elements you wanted, and can be sorted and printed:
r.sort()
print r
[[], [1], [1, 2], [1, 2, 3], [1, 2, 3, 4], [1, 2, 4], [1, 3], [1, 3, 4], [1, 4], [2], [2, 3], [2, 3, 4], [2, 4], [3], [3, 4], [4]]
[[][]]
, to fix that just separate the cases for length checking if len(seq) == 0: yield [] elif len(seq) == 1: yield seq yield []
– Ayush
Oct 18 '17 at 18:32
def powerset(lst):
return reduce(lambda result, x: result + [subset + [x] for subset in result],
lst, [[]])
There is a refinement of powerset:
def powerset(seq):
"""
Returns all the subsets of this set. This is a generator.
"""
if len(seq) <= 0:
yield []
else:
for item in powerset(seq[1:]):
yield [seq[0]]+item
yield item
I know I have previously added an answer, but I really like my new implementation. I am taking a set as input, but it actually could be any iterable, and I am returning a set of sets which is the power set of the input. I like this approach because it is more aligned with the mathematical definition of power set (set of all subsets).
def power_set(A):
"""A is an iterable (list, tuple, set, str, etc)
returns a set which is the power set of A."""
length = len(A)
l = [a for a in A]
ps = set()
for i in range(2 ** length):
selector = f'{i:0{length}b}'
subset = {l[j] for j, bit in enumerate(selector) if bit == '1'}
ps.add(frozenset(subset))
return ps
If you want exactly the output you posted in your answer use this:
>>> [set(s) for s in power_set({1, 2, 3, 4})]
[{3, 4},
{2},
{1, 4},
{2, 3, 4},
{2, 3},
{1, 2, 4},
{1, 2},
{1, 2, 3},
{3},
{2, 4},
{1},
{1, 2, 3, 4},
set(),
{1, 3},
{1, 3, 4},
{4}]
It is known that the number of elements of the power set is 2 ** len(A)
, so that could clearly be seen in the for
loop.
I need to convert the input (ideally a set) into a list because by a set is a data structure of unique unordered elements, and the order will be crucial to generate the subsets.
selector
is key in this algorithm. Note that selector
has the same length as the input set, and to make this possible it is using an f-string with padding. Basically, this allows me to select the elements that will be added to each subset during each iteration. Let's say the input set has 3 elements {0, 1, 2}
, so selector will take values between 0 and 7 (inclusive), which in binary are:
000 # 0
001 # 1
010 # 2
011 # 3
100 # 4
101 # 5
110 # 6
111 # 7
So, each bit could serve as an indicator if an element of the original set should be added or not. Look at the binary numbers, and just think of each number as an element of the super set in which 1
means that an element at index j
should be added, and 0
means that this element should not be added.
I am using a set comprehension to generate a subset at each iteration, and I convert this subset into a frozenset
so I can add it to ps
(power set). Otherwise, I won't be able to add it because a set in Python consists only of immutable objects.
You can simplify the code using some python comprehensions, so you can get rid of those for loops. You can also use zip
to avoid using j
index and the code will end up as the following:
def power_set(A):
length = len(A)
return {
frozenset({e for e, b in zip(A, f'{i:{length}b}') if b == '1'})
for i in range(2 ** length)
}
That's it. What I like of this algorithm is that is clearer and more intuitive than others because it looks quite magical to rely on itertools
even though it works as expected.
def get_power_set(s):
power_set=[[]]
for elem in s:
# iterate over the sub sets so far
for sub_set in power_set:
# add a new subset consisting of the subset at hand added elem
power_set=power_set+[list(sub_set)+[elem]]
return power_set
For example:
get_power_set([1,2,3])
yield
[[], [1], [2], [1, 2], [3], [1, 3], [2, 3], [1, 2, 3]]
power_set
) in the loop that it governs is a very questionable practice. For example, suppose you wrote this instead of the proposed variable-modifying code: power_set += [list(sub_set)+[elem]]
. Then the loop does not terminate.
– hughdbrown
May 25 '16 at 5:24
I have found the following algorithm very clear and simple:
def get_powerset(some_list):
"""Returns all subsets of size 0 - len(some_list) for some_list"""
if len(some_list) == 0:
return [[]]
subsets = []
first_element = some_list[0]
remaining_list = some_list[1:]
# Strategy: get all the subsets of remaining_list. For each
# of those subsets, a full subset list will contain both
# the original subset as well as a version of the subset
# that contains first_element
for partial_subset in get_powerset(remaining_list):
subsets.append(partial_subset)
subsets.append(partial_subset[:] + [first_element])
return subsets
Another way one can generate the powerset is by generating all binary numbers that have n
bits. As a power set the amount of number with n
digits is 2 ^ n
. The principle of this algorithm is that an element could be present or not in a subset as a binary digit could be one or zero but not both.
def power_set(items):
N = len(items)
# enumerate the 2 ** N possible combinations
for i in range(2 ** N):
combo = []
for j in range(N):
# test bit jth of integer i
if (i >> j) % 2 == 1:
combo.append(items[j])
yield combo
I found both algorithms when I was taking MITx: 6.00.2x Introduction to Computational Thinking and Data Science, and I consider it is one of the easiest algorithms to understand I have seen.
I just wanted to provide the most comprehensible solution, the anti code-golf version.
from itertools import combinations
l = ["x", "y", "z", ]
def powerset(items):
combo = []
for r in range(len(items) + 1):
#use a list to coerce a actual list from the combinations generator
combo.append(list(combinations(items,r)))
return combo
l_powerset = powerset(l)
for i, item in enumerate(l_powerset):
print "All sets of length ", i
print item
The results
All sets of length 0
[()]
All sets of length 1
[('x',), ('y',), ('z',)]
All sets of length 2
[('x', 'y'), ('x', 'z'), ('y', 'z')]
All sets of length 3
[('x', 'y', 'z')]
For more see the itertools docs, also the wikipedia entry on power sets
Just a quick power set refresher !
Power set of a set X, is simply the set of all subsets of X including the empty set
Example set X = (a,b,c)
Power Set = { { a , b , c } , { a , b } , { a , c } , { b , c } , { a } , { b } , { c } , { } }
Here is another way of finding power set:
def power_set(input):
# returns a list of all subsets of the list a
if (len(input) == 0):
return [[]]
else:
main_subset = [ ]
for small_subset in power_set(input[1:]):
main_subset += [small_subset]
main_subset += [[input[0]] + small_subset]
return main_subset
print(power_set([0,1,2,3]))
full credit to source
With empty set, which is part of all the subsets, you could use:
def subsets(iterable):
for n in range(len(iterable) + 1):
yield from combinations(iterable, n)
A simple way would be to harness the internal representation of integers under 2's complement arithmetic.
Binary representation of integers is as {000, 001, 010, 011, 100, 101, 110, 111} for numbers ranging from 0 to 7. For an integer counter value, considering 1 as inclusion of corresponding element in collection and '0' as exclusion we can generate subsets based on the counting sequence. Numbers have to be generated from 0
to pow(2,n) -1
where n is the length of array i.e. number of bits in binary representation.
A simple Subset Generator Function based on it can be written as below. It basically relies
def subsets(array):
if not array:
return
else:
length = len(array)
for max_int in range(0x1 << length):
subset = []
for i in range(length):
if max_int & (0x1 << i):
subset.append(array[i])
yield subset
and then it can be used as
def get_subsets(array):
powerset = []
for i in subsets(array):
powerser.append(i)
return powerset
Testing
Adding following in local file
if __name__ == '__main__':
sample = ['b', 'd', 'f']
for i in range(len(sample)):
print "Subsets for " , sample[i:], " are ", get_subsets(sample[i:])
gives following output
Subsets for ['b', 'd', 'f'] are [[], ['b'], ['d'], ['b', 'd'], ['f'], ['b', 'f'], ['d', 'f'], ['b', 'd', 'f']]
Subsets for ['d', 'f'] are [[], ['d'], ['f'], ['d', 'f']]
Subsets for ['f'] are [[], ['f']]
Almost all of these answers use list
rather than set
, which felt like a bit of a cheat to me. So, out of curiosity I tried to do a simple version truly on set
and summarize for other "new to Python" folks.
I found there's a couple oddities in dealing with Python's set implementation. The main surprise to me was handling empty sets. This is in contrast to Ruby's Set implementation, where I can simply do Set[Set[]]
and get a Set
containing one empty Set
, so I found it initially a little confusing.
To review, in doing powerset
with set
s, I encountered two problems:
set()
takes an iterable, so set(set())
will return set()
because the empty set iterable is empty (duh I guess :))set({set()})
and set.add(set)
won't work because set()
isn't hashableTo solve both issues, I made use of frozenset()
, which means I don't quite get what I want (type is literally set
), but makes use of the overall set
interace.
def powerset(original_set):
# below gives us a set with one empty set in it
ps = set({frozenset()})
for member in original_set:
subset = set()
for m in ps:
# to be added into subset, needs to be
# frozenset.union(set) so it's hashable
subset.add(m.union(set([member]))
ps = ps.union(subset)
return ps
Below we get 2² (16) frozenset
s correctly as output:
In [1]: powerset(set([1,2,3,4]))
Out[2]:
{frozenset(),
frozenset({3, 4}),
frozenset({2}),
frozenset({1, 4}),
frozenset({3}),
frozenset({2, 3}),
frozenset({2, 3, 4}),
frozenset({1, 2}),
frozenset({2, 4}),
frozenset({1}),
frozenset({1, 2, 4}),
frozenset({1, 3}),
frozenset({1, 2, 3}),
frozenset({4}),
frozenset({1, 3, 4}),
frozenset({1, 2, 3, 4})}
As there's no way to have a set
of set
s in Python, if you want to turn these frozenset
s into set
s, you'll have to map them back into a list
(list(map(set, powerset(set([1,2,3,4]))))
) or modify the above.
Perhaps the question is getting old, but I hope my code will help someone.
def powSet(set):
if len(set) == 0:
return [[]]
return addtoAll(set[0],powSet(set[1:])) + powSet(set[1:])
def addtoAll(e, set):
for c in set:
c.append(e)
return set
Use function powerset()
from package more_itertools
.
Yields all possible subsets of the iterable
>>> list(powerset([1, 2, 3]))
[(), (1,), (2,), (3,), (1, 2), (1, 3), (2, 3), (1, 2, 3)]
If you want sets, use:
list(map(set, powerset(iterable)))
Getting all the subsets with recursion. Crazy-ass one-liner
from typing import List
def subsets(xs: list) -> List[list]:
return subsets(xs[1:]) + [x + [xs[0]] for x in subsets(xs[1:])] if xs else [[]]
Based on a Haskell solution
subsets :: [a] -> [[a]]
subsets [] = [[]]
subsets (x:xs) = map (x:) (subsets xs) ++ subsets xs
def findsubsets(s, n):
return list(itertools.combinations(s, n))
def allsubsets(s) :
a = []
for x in range(1,len(s)+1):
a.append(map(set,findsubsets(s,x)))
return a
This is wild because none of these answers actually provide the return of an actual Python set. Here is a messy implementation that will give a powerset that actually is a Python set
.
test_set = set(['yo', 'whatup', 'money'])
def powerset( base_set ):
""" modified from pydoc's itertools recipe shown above"""
from itertools import chain, combinations
base_list = list( base_set )
combo_list = [ combinations(base_list, r) for r in range(len(base_set)+1) ]
powerset = set([])
for ll in combo_list:
list_of_frozensets = list( map( frozenset, map( list, ll ) ) )
set_of_frozensets = set( list_of_frozensets )
powerset = powerset.union( set_of_frozensets )
return powerset
print powerset( test_set )
# >>> set([ frozenset(['money','whatup']), frozenset(['money','whatup','yo']),
# frozenset(['whatup']), frozenset(['whatup','yo']), frozenset(['yo']),
# frozenset(['money','yo']), frozenset(['money']), frozenset([]) ])
I'd love to see a better implementation, though.
[*map(set, chain.from_iterable(combinations(s, r) for r in range(len(s)+1)))]
; the function arg of map
can be frozenset
if you prefer.
– PM 2Ring
Oct 11 '18 at 18:32
Here is my quick implementation utilizing combinations but using only built-ins.
def powerSet(array):
length = str(len(array))
formatter = '{:0' + length + 'b}'
combinations = []
for i in xrange(2**int(length)):
combinations.append(formatter.format(i))
sets = set()
currentSet = []
for combo in combinations:
for i,val in enumerate(combo):
if val=='1':
currentSet.append(array[i])
sets.add(tuple(sorted(currentSet)))
currentSet = []
return sets
All subsets in range n as set:
n = int(input())
l = [i for i in range (1, n + 1)]
for number in range(2 ** n) :
binary = bin(number)[: 1 : -1]
subset = [l[i] for i in range(len(binary)) if binary[i] == "1"]
print(set(sorted(subset)) if number > 0 else "{}")
import math
def printPowerSet(set,set_size):
pow_set_size =int(math.pow(2, set_size))
for counter in range(pow_set_size):
for j in range(set_size):
if((counter & (1 << j)) > 0):
print(set[j], end = "")
print("")
set = ['a', 'b', 'c']
printPowerSet(set,3)
A variation of the question, is an exercise I see on the book "Discovering Computer Science: Interdisciplinary Problems, Principles, and Python Programming. 2015 edition". In that exercise 10.2.11, the input is just an integer number, and the output should be the power sets. Here is my recursive solution (not using anything else but basic python3 )
def powerSetR(n):
assert n >= 0
if n == 0:
return [[]]
else:
input_set = list(range(1, n+1)) # [1,2,...n]
main_subset = [ ]
for small_subset in powerSetR(n-1):
main_subset += [small_subset]
main_subset += [ [input_set[-1]] + small_subset]
return main_subset
superset = powerSetR(4)
print(superset)
print("Number of sublists:", len(superset))
And the output is
[[], [4], [3], [4, 3], [2], [4, 2], [3, 2], [4, 3, 2], [1], [4, 1], [3, 1], [4, 3, 1], [2, 1], [4, 2, 1], [3, 2, 1], [4, 3, 2, 1]] Number of sublists: 16
I hadn't come across the more_itertools.powerset
function and would recommend using that. I also recommend not using the default ordering of the output from itertools.combinations
, often instead you want to minimise the distance between the positions and sort the subsets of items with shorter distance between them above/before the items with larger distance between them.
The itertools
recipes page shows it uses chain.from_iterable
r
here matches the standard notation for the lower part of a binomial coefficient, the s
is usually referred to as n
in mathematics texts and on calculators (“n Choose r”)def powerset(iterable):
"powerset([1,2,3]) --> () (1,) (2,) (3,) (1,2) (1,3) (2,3) (1,2,3)"
s = list(iterable)
return chain.from_iterable(combinations(s, r) for r in range(len(s)+1))
The other examples here give the powerset of [1,2,3,4]
in such a way that the 2-tuples are listed in "lexicographic" order (when we print the numbers as integers). If I write the distance between the numbers alongside it (i.e. the difference), it shows my point:
12 ⇒ 1
13 ⇒ 2
14 ⇒ 3
23 ⇒ 1
24 ⇒ 2
34 ⇒ 1
The correct order for subsets should be the order which 'exhausts' the minimal distance first, like so:
12 ⇒ 1
23 ⇒ 1
34 ⇒ 1
13 ⇒ 2
24 ⇒ 2
14 ⇒ 3
Using numbers here makes this ordering look 'wrong', but consider for example the letters ["a","b","c","d"]
it is clearer why this might be useful to obtain the powerset in this order:
ab ⇒ 1
bc ⇒ 1
cd ⇒ 1
ac ⇒ 2
bd ⇒ 2
ad ⇒ 3
This effect is more pronounced with more items, and for my purposes it makes the difference between being able to describe the ranges of the indexes of the powerset meaningfully.
(There is a lot written on Gray codes etc. for the output order of algorithms in combinatorics, I don't see it as a side issue).
I actually just wrote a fairly involved program which used this fast integer partition code to output the values in the proper order, but then I discovered more_itertools.powerset
and for most uses it's probably fine to just use that function like so:
from more_itertools import powerset
from numpy import ediff1d
def ps_sorter(tup):
l = len(tup)
d = ediff1d(tup).tolist()
return l, d
ps = powerset([1,2,3,4])
ps = sorted(ps, key=ps_sorter)
for x in ps:
print(x)
⇣
()
(1,)
(2,)
(3,)
(4,)
(1, 2)
(2, 3)
(3, 4)
(1, 3)
(2, 4)
(1, 4)
(1, 2, 3)
(2, 3, 4)
(1, 2, 4)
(1, 3, 4)
(1, 2, 3, 4)
I wrote some more involved code which will print the powerset nicely (see the repo for pretty printing functions I've not included here: print_partitions
, print_partitions_by_length
, and pprint_tuple
).
pset_partitions.py
This is all pretty simple, but still might be useful if you want some code that'll let you get straight to accessing the different levels of the powerset:
from itertools import permutations as permute
from numpy import cumsum
# http://jeromekelleher.net/generating-integer-partitions.html
# via
# https://stackoverflow.com/questions/10035752/elegant-python-code-for-integer-partitioning#comment25080713_10036764
def asc_int_partitions(n):
a = [0 for i in range(n + 1)]
k = 1
y = n - 1
while k != 0:
x = a[k - 1] + 1
k -= 1
while 2 * x <= y:
a[k] = x
y -= x
k += 1
l = k + 1
while x <= y:
a[k] = x
a[l] = y
yield tuple(a[:k + 2])
x += 1
y -= 1
a[k] = x + y
y = x + y - 1
yield tuple(a[:k + 1])
# https://stackoverflow.com/a/6285330/2668831
def uniquely_permute(iterable, enforce_sort=False, r=None):
previous = tuple()
if enforce_sort: # potential waste of effort (default: False)
iterable = sorted(iterable)
for p in permute(iterable, r):
if p > previous:
previous = p
yield p
def sum_min(p):
return sum(p), min(p)
def partitions_by_length(max_n, sorting=True, permuting=False):
partition_dict = {0: ()}
for n in range(1,max_n+1):
partition_dict.setdefault(n, [])
partitions = list(asc_int_partitions(n))
for p in partitions:
if permuting:
perms = uniquely_permute(p)
for perm in perms:
partition_dict.get(len(p)).append(perm)
else:
partition_dict.get(len(p)).append(p)
if not sorting:
return partition_dict
for k in partition_dict:
partition_dict.update({k: sorted(partition_dict.get(k), key=sum_min)})
return partition_dict
def print_partitions_by_length(max_n, sorting=True, permuting=True):
partition_dict = partitions_by_length(max_n, sorting=sorting, permuting=permuting)
for k in partition_dict:
if k == 0:
print(tuple(partition_dict.get(k)), end="")
for p in partition_dict.get(k):
print(pprint_tuple(p), end=" ")
print()
return
def generate_powerset(items, subset_handler=tuple, verbose=False):
"""
Generate the powerset of an iterable `items`.
Handling of the elements of the iterable is by whichever function is passed as
`subset_handler`, which must be able to handle the `None` value for the
empty set. The function `string_handler` will join the elements of the subset
with the empty string (useful when `items` is an iterable of `str` variables).
"""
ps = {0: [subset_handler()]}
n = len(items)
p_dict = partitions_by_length(n-1, sorting=True, permuting=True)
for p_len, parts in p_dict.items():
ps.setdefault(p_len, [])
if p_len == 0:
# singletons
for offset in range(n):
subset = subset_handler([items[offset]])
if verbose:
if offset > 0:
print(end=" ")
if offset == n - 1:
print(subset, end="\n")
else:
print(subset, end=",")
ps.get(p_len).append(subset)
for pcount, partition in enumerate(parts):
distance = sum(partition)
indices = (cumsum(partition)).tolist()
for offset in range(n - distance):
subset = subset_handler([items[offset]] + [items[offset:][i] for i in indices])
if verbose:
if offset > 0:
print(end=" ")
if offset == n - distance - 1:
print(subset, end="\n")
else:
print(subset, end=",")
ps.get(p_len).append(subset)
if verbose and p_len < n-1:
print()
return ps
As an example, I wrote a CLI demo program which takes a string as a command line argument:
python string_powerset.py abcdef
⇣
a, b, c, d, e, f
ab, bc, cd, de, ef
ac, bd, ce, df
ad, be, cf
ae, bf
af
abc, bcd, cde, def
abd, bce, cdf
acd, bde, cef
abe, bcf
ade, bef
ace, bdf
abf
aef
acf
adf
abcd, bcde, cdef
abce, bcdf
abde, bcef
acde, bdef
abcf
abef
adef
abdf
acdf
acef
abcde, bcdef
abcdf
abcef
abdef
acdef
abcdef
In Python 3.5 or greater, you can use the yield from
statement along with itertools.combinations:
def subsets(iterable):
for n in range(len(iterable)):
yield from combinations(iterable, n + 1)