# How do I generate all permutations of a list?

How do I generate all the permutations of a list? For example:

``````permutations([])
[]

permutations([1])
[1]

permutations([1, 2])
[1, 2]
[2, 1]

permutations([1, 2, 3])
[1, 2, 3]
[1, 3, 2]
[2, 1, 3]
[2, 3, 1]
[3, 1, 2]
[3, 2, 1]
``````

Use `itertools.permutations` from the standard library:

``````import itertools
list(itertools.permutations([1, 2, 3]))
``````

Adapted from here is a demonstration of how `itertools.permutations` might be implemented:

``````def permutations(elements):
if len(elements) <= 1:
yield elements
return
for perm in permutations(elements[1:]):
for i in range(len(elements)):
# nb elements[0:1] works in both string and list contexts
yield perm[:i] + elements[0:1] + perm[i:]
``````

A couple of alternative approaches are listed in the documentation of `itertools.permutations`. Here's one:

``````def permutations(iterable, r=None):
# permutations('ABCD', 2) --> AB AC AD BA BC BD CA CB CD DA DB DC
# permutations(range(3)) --> 012 021 102 120 201 210
pool = tuple(iterable)
n = len(pool)
r = n if r is None else r
if r > n:
return
indices = range(n)
cycles = range(n, n-r, -1)
yield tuple(pool[i] for i in indices[:r])
while n:
for i in reversed(range(r)):
cycles[i] -= 1
if cycles[i] == 0:
indices[i:] = indices[i+1:] + indices[i:i+1]
cycles[i] = n - i
else:
j = cycles[i]
indices[i], indices[-j] = indices[-j], indices[i]
yield tuple(pool[i] for i in indices[:r])
break
else:
return
``````

And another, based on `itertools.product`:

``````def permutations(iterable, r=None):
pool = tuple(iterable)
n = len(pool)
r = n if r is None else r
for indices in product(range(n), repeat=r):
if len(set(indices)) == r:
yield tuple(pool[i] for i in indices)
``````
• This and other recursive solutions have a potential hazard of eating up all the RAM if the permutated list is big enough May 27, 2009 at 7:05
• They also reach the recursion limit (and die) with large lists
– dbr
Jun 9, 2009 at 3:12
• bgbg, dbr: Its using a generator, so the function itself won't eat up memory. Its left to you on how to consume the iterator returned by all_perms (say you could write each iteration to disk and not worry about memory). I know this post is old but I'm writing this for the benefit of everyone who reads it now. Also now, the best way would be to use itertools.permutations() as pointed out by many. May 2, 2011 at 12:40
• Not just a generator. It's using nested generators, which each yield to the previous one up the call stack, in case that's not clear. It uses O(n) memory, which is good. Jul 19, 2011 at 19:02
• PS: I fixed it, with `for i in range(len(elements))` instead of `for i in range(len(elements)+1)`. In fact, the singled-out element `elements[0:1]` can be in `len(elements)` different positions, in the result, not `len(elements)+1`. May 29, 2012 at 13:48

For Python 2.6 onwards:

``````import itertools
itertools.permutations([1, 2, 3])
``````

This returns as a generator. Use `list(permutations(xs))` to return as a list.

• Notice that there exists an `r` parameter, e.g. `itertools.permutations([1,2,3], r=2)`, which will generate all possible permutations selecting 2 elements: `[(1, 2), (1, 3), (2, 1), (2, 3), (3, 1), (3, 2)]` Aug 24, 2017 at 8:49

First, import `itertools`:

``````import itertools
``````

### Permutation (order matters):

``````print(list(itertools.permutations([1,2,3,4], 2)))

[(1, 2), (1, 3), (1, 4),
(2, 1), (2, 3), (2, 4),
(3, 1), (3, 2), (3, 4),
(4, 1), (4, 2), (4, 3)]
``````

### Combination (order does NOT matter):

``````print(list(itertools.combinations('123', 2)))

[('1', '2'), ('1', '3'), ('2', '3')]
``````

### Cartesian product (with several iterables):

``````print(list(itertools.product([1,2,3], [4,5,6])))

[(1, 4), (1, 5), (1, 6),
(2, 4), (2, 5), (2, 6),
(3, 4), (3, 5), (3, 6)]
``````

### Cartesian product (with one iterable and itself):

``````print(list(itertools.product([1,2], repeat=3)))

[(1, 1, 1), (1, 1, 2), (1, 2, 1), (1, 2, 2),
(2, 1, 1), (2, 1, 2), (2, 2, 1), (2, 2, 2)]
``````
• Jan 30, 2013 at 17:59
``````def permutations(head, tail=''):
print(tail)
else:
``````

called as:

``````permutations('abc')
``````
• Why print tail and then return None? Why not return tail instead? Why not return anything anyways? Nov 27, 2017 at 11:48
• @bugmenot123 you probably want all of the final tails rather than just tail, this is done easily by adding a `perms=[]` parameter to the function, appending to it on every `print` and having a final `return perms` Jan 3, 2021 at 3:48
``````#!/usr/bin/env python

def perm(a, k=0):
if k == len(a):
print a
else:
for i in xrange(k, len(a)):
a[k], a[i] = a[i] ,a[k]
perm(a, k+1)
a[k], a[i] = a[i], a[k]

perm([1,2,3])
``````

Output:

``````[1, 2, 3]
[1, 3, 2]
[2, 1, 3]
[2, 3, 1]
[3, 2, 1]
[3, 1, 2]
``````

As I'm swapping the content of the list it's required a mutable sequence type as input. E.g. `perm(list("ball"))` will work and `perm("ball")` won't because you can't change a string.

This Python implementation is inspired by the algorithm presented in the book Computer Algorithms by Horowitz, Sahni and Rajasekeran.

• I assume k is the length or permutations. For k = 2 outputs [1, 2, 3]. Shouldn't it be (1, 2) (1, 3) (2, 1) (2, 3) (3, 1) (3, 2) ?? Feb 24, 2019 at 22:13
• k is the index of the element you want to swap May 9, 2020 at 20:24
• NameError: name 'xrange' is not defined Apr 4, 2021 at 20:21
• 7 years later, how would I return a list of lists of all the permuted lists? Also, can this be done iteratively? Apr 24, 2021 at 0:46
• this is done easily by adding a perms=[] parameter to the function, appending to it on every print and having a final return perms Jan 27, 2022 at 6:18

This solution implements a generator, to avoid holding all the permutations on memory:

``````def permutations (orig_list):
if not isinstance(orig_list, list):
orig_list = list(orig_list)

yield orig_list

if len(orig_list) == 1:
return

for n in sorted(orig_list):
new_list = orig_list[:]
pos = new_list.index(n)
del(new_list[pos])
new_list.insert(0, n)
for resto in permutations(new_list[1:]):
if new_list[:1] + resto <> orig_list:
yield new_list[:1] + resto
``````

Regular implementation (no yield - will do everything in memory):

``````def getPermutations(array):
if len(array) == 1:
return [array]
permutations = []
for i in range(len(array)):
# get all perm's of subarray w/o current item
perms = getPermutations(array[:i] + array[i+1:])
for p in perms:
permutations.append([array[i], *p])
return permutations
``````

Yield implementation:

``````def getPermutations(array):
if len(array) == 1:
yield array
else:
for i in range(len(array)):
perms = getPermutations(array[:i] + array[i+1:])
for p in perms:
yield [array[i], *p]
``````

The basic idea is to go over all the elements in the array for the 1st position, and then in 2nd position go over all the rest of the elements without the chosen element for the 1st, etc. You can do this with recursion, where the stop criteria is getting to an array of 1 element - in which case you return that array.

• This does not work for me _> ValueError: operands could not be broadcast together with shapes (0,) (2,) , for this line: `perms = getPermutations(array[:i] + array[i+1:])`
– RK1
Feb 6, 2020 at 15:29
• @RK1 what was the input? Feb 6, 2020 at 21:19
• I'm passing in a `numpy` array _> `getPermutations(np.array([1, 2, 3]))`, I see it works for a list, just got confused as the func arg is `array` :)
– RK1
Feb 7, 2020 at 8:24
• @RK1 glad it works :-) list is a keyword in python, so it's usually not a good idea to call your parameter a keyword, as it will "shadow" it. So I use the word array, as this is the actual functionality of the list that I'm using - their array like manner. I guess if I would write documentation I would clarify it. Also I believe that basic "interview" questions should be solved without external packages, like numpy. Feb 7, 2020 at 9:02
• Haha that's true, yeah was trying to use it with `numba` and got greedy with speed so tried to use it exclusively with `numpy` arrays
– RK1
Feb 7, 2020 at 9:21

In a functional style

``````def addperm(x,l):
return [ l[0:i] + [x] + l[i:]  for i in range(len(l)+1) ]

def perm(l):
if len(l) == 0:
return [[]]
return [x for y in perm(l[1:]) for x in addperm(l[0],y) ]

print perm([ i for i in range(3)])
``````

The result:

``````[[0, 1, 2], [1, 0, 2], [1, 2, 0], [0, 2, 1], [2, 0, 1], [2, 1, 0]]
``````

The following code is an in-place permutation of a given list, implemented as a generator. Since it only returns references to the list, the list should not be modified outside the generator. The solution is non-recursive, so uses low memory. Work well also with multiple copies of elements in the input list.

``````def permute_in_place(a):
a.sort()
yield list(a)

if len(a) <= 1:
return

first = 0
last = len(a)
while 1:
i = last - 1

while 1:
i = i - 1
if a[i] < a[i+1]:
j = last - 1
while not (a[i] < a[j]):
j = j - 1
a[i], a[j] = a[j], a[i] # swap the values
r = a[i+1:last]
r.reverse()
a[i+1:last] = r
yield list(a)
break
if i == first:
a.reverse()
return

if __name__ == '__main__':
for n in range(5):
for a in permute_in_place(range(1, n+1)):
print a
print

for a in permute_in_place([0, 0, 1, 1, 1]):
print a
print
``````

A quite obvious way in my opinion might be also:

``````def permutList(l):
if not l:
return [[]]
res = []
for e in l:
temp = l[:]
temp.remove(e)
res.extend([[e] + r for r in permutList(temp)])

return res
``````
``````list2Perm = [1, 2.0, 'three']
listPerm = [[a, b, c]
for a in list2Perm
for b in list2Perm
for c in list2Perm
if ( a != b and b != c and a != c )
]
print listPerm
``````

Output:

``````[
[1, 2.0, 'three'],
[1, 'three', 2.0],
[2.0, 1, 'three'],
[2.0, 'three', 1],
['three', 1, 2.0],
['three', 2.0, 1]
]
``````
• While it technically produces the desired output, you're solving something that could be O(n lg n) in O(n^n) - "slightly" inefficient for large sets. Aug 22, 2011 at 3:23
• @James: I am a little confused by the O(n log n) that you give: the number of permutations is n!, which is already much larger than O(n log n); so, I can't see how a solution could be O(n log n). However, it is true that this solution is in O(n^n), which is much larger than n!, as is clear from Stirling's approximation. May 29, 2012 at 13:38

I used an algorithm based on the factorial number system- For a list of length n, you can assemble each permutation item by item, selecting from the items left at each stage. You have n choices for the first item, n-1 for the second, and only one for the last, so you can use the digits of a number in the factorial number system as the indices. This way the numbers 0 through n!-1 correspond to all possible permutations in lexicographic order.

``````from math import factorial
def permutations(l):
permutations=[]
length=len(l)
for x in xrange(factorial(length)):
available=list(l)
newPermutation=[]
for radix in xrange(length, 0, -1):
index=x/placeValue
newPermutation.append(available.pop(index))
x-=index*placeValue
permutations.append(newPermutation)
return permutations

permutations(range(3))
``````

output:

``````[[0, 1, 2], [0, 2, 1], [1, 0, 2], [1, 2, 0], [2, 0, 1], [2, 1, 0]]
``````

This method is non-recursive, but it is slightly slower on my computer and xrange raises an error when n! is too large to be converted to a C long integer (n=13 for me). It was enough when I needed it, but it's no itertools.permutations by a long shot.

• Hi, welcome to Stack Overflow. Although posting the brute force method has its merits, if you don't think your solution is better than the accepted solution, you probably shouldn't post it (especially on an old question that already has so many answers). Aug 8, 2013 at 20:43
• I was actually looking for a brute-force non-library approach, so thanks! Jul 1, 2016 at 19:16
• I found it useful too! Oct 11, 2020 at 1:42

Note that this algorithm has an `n factorial` time complexity, where `n` is the length of the input list

Print the results on the run:

``````global result
result = []

def permutation(li):
if li == [] or li == None:
return

if len(li) == 1:
result.append(li[0])
print result
result.pop()
return

for i in range(0,len(li)):
result.append(li[i])
permutation(li[:i] + li[i+1:])
result.pop()
``````

Example:

``````permutation([1,2,3])
``````

Output:

``````[1, 2, 3]
[1, 3, 2]
[2, 1, 3]
[2, 3, 1]
[3, 1, 2]
[3, 2, 1]
``````

One can indeed iterate over the first element of each permutation, as in tzwenn's answer. It is however more efficient to write this solution this way:

``````def all_perms(elements):
if len(elements) <= 1:
yield elements  # Only permutation possible = no permutation
else:
# Iteration over the first element in the result permutation:
for (index, first_elmt) in enumerate(elements):
other_elmts = elements[:index]+elements[index+1:]
for permutation in all_perms(other_elmts):
yield [first_elmt] + permutation
``````

This solution is about 30 % faster, apparently thanks to the recursion ending at `len(elements) <= 1` instead of `0`. It is also much more memory-efficient, as it uses a generator function (through `yield`), like in Riccardo Reyes's solution.

This is inspired by the Haskell implementation using list comprehension:

``````def permutation(list):
if len(list) == 0:
return [[]]
else:
return [[x] + ys for x in list for ys in permutation(delete(list, x))]

def delete(list, item):
lc = list[:]
lc.remove(item)
return lc
``````

For performance, a numpy solution inspired by Knuth, (p22) :

``````from numpy import empty, uint8
from math import factorial

def perms(n):
f = 1
p = empty((2*n-1, factorial(n)), uint8)
for i in range(n):
p[i, :f] = i
p[i+1:2*i+1, :f] = p[:i, :f]  # constitution de blocs
for j in range(i):
p[:i+1, f*(j+1):f*(j+2)] = p[j+1:j+i+2, :f]  # copie de blocs
f = f*(i+1)
return p[:n, :]
``````

Copying large blocs of memory saves time - it's 20x faster than `list(itertools.permutations(range(n))` :

``````In [1]: %timeit -n10 list(permutations(range(10)))
10 loops, best of 3: 815 ms per loop

In [2]: %timeit -n100 perms(10)
100 loops, best of 3: 40 ms per loop
``````

If you don't want to use the builtin methods such as:

``````import itertools
list(itertools.permutations([1, 2, 3]))
``````

you can implement permute function yourself

``````from collections.abc import Iterable

def permute(iterable: Iterable[str]) -> set[str]:
perms = set()

if len(iterable) == 1:
return {*iterable}

for index, char in enumerate(iterable):
perms.update([char + perm for perm in permute(iterable[:index] + iterable[index + 1:])])

return perms

if __name__ == '__main__':
print(permute('abc'))
# {'bca', 'abc', 'cab', 'acb', 'cba', 'bac'}
print(permute(['1', '2', '3']))
# {'123', '312', '132', '321', '213', '231'}
``````

Disclaimer: shameless plug by package author. :)

The trotter package is different from most implementations in that it generates pseudo lists that don't actually contain permutations but rather describe mappings between permutations and respective positions in an ordering, making it possible to work with very large 'lists' of permutations, as shown in this demo which performs pretty instantaneous operations and look-ups in a pseudo-list 'containing' all the permutations of the letters in the alphabet, without using more memory or processing than a typical web page.

In any case, to generate a list of permutations, we can do the following.

``````import trotter

my_permutations = trotter.Permutations(3, [1, 2, 3])

print(my_permutations)

for p in my_permutations:
print(p)
``````

Output:

```A pseudo-list containing 6 3-permutations of [1, 2, 3].
[1, 2, 3]
[1, 3, 2]
[3, 1, 2]
[3, 2, 1]
[2, 3, 1]
[2, 1, 3]
```
• Your package have a limit between 400 - 500 elements. Jun 19, 2022 at 18:06
• @ecdani Thanks for your interest in this library! If each atom in the Milky Way galaxy spontaneously turned into a new Milky Way galaxy, and each of the new atoms did that again, we still wouldn't have as many atoms as there are permutations of 500 elements. Having said that, if you up your system's maximum recursion level a bit, the library can easily represent permutations of 1,000 or more elements, and searching and lookup are still pretty instantaneous. If you like, post an issue at the trotter repository page. Jun 25, 2022 at 15:19

The beauty of recursion:

``````>>> import copy
>>> def perm(prefix,rest):
...      for e in rest:
...              new_rest=copy.copy(rest)
...              new_prefix=copy.copy(prefix)
...              new_prefix.append(e)
...              new_rest.remove(e)
...              if len(new_rest) == 0:
...                      print new_prefix + new_rest
...                      continue
...              perm(new_prefix,new_rest)
...
>>> perm([],['a','b','c','d'])
['a', 'b', 'c', 'd']
['a', 'b', 'd', 'c']
['a', 'c', 'b', 'd']
['a', 'c', 'd', 'b']
['a', 'd', 'b', 'c']
['a', 'd', 'c', 'b']
['b', 'a', 'c', 'd']
['b', 'a', 'd', 'c']
['b', 'c', 'a', 'd']
['b', 'c', 'd', 'a']
['b', 'd', 'a', 'c']
['b', 'd', 'c', 'a']
['c', 'a', 'b', 'd']
['c', 'a', 'd', 'b']
['c', 'b', 'a', 'd']
['c', 'b', 'd', 'a']
['c', 'd', 'a', 'b']
['c', 'd', 'b', 'a']
['d', 'a', 'b', 'c']
['d', 'a', 'c', 'b']
['d', 'b', 'a', 'c']
['d', 'b', 'c', 'a']
['d', 'c', 'a', 'b']
['d', 'c', 'b', 'a']
``````

ANOTHER APPROACH (without libs)

``````def permutation(input):
if len(input) == 1:
return input if isinstance(input, list) else [input]

result = []
for i in range(len(input)):
first = input[i]
rest = input[:i] + input[i + 1:]
rest_permutation = permutation(rest)
for p in rest_permutation:
result.append(first + p)
return result
``````

Input can be a string or a list

``````print(permutation('abcd'))
print(permutation(['a', 'b', 'c', 'd']))
``````
• This does not work for a list with integers, eg. `[1, 2, 3]` returns `[6, 6, 6, 6, 6, 6]`
– RK1
Feb 6, 2020 at 15:50
• @RK1, u can try this `print(permutation(['1','2','3']))` Feb 7, 2020 at 5:42
``````from __future__ import print_function

def perm(n):
p = []
for i in range(0,n+1):
p.append(i)
while True:
for i in range(1,n+1):
print(p[i], end=' ')
print("")
i = n - 1
found = 0
if p[i]<p[i+1]:
found = 1
else:
i = i - 1
k = n
while p[i]>p[k]:
k = k - 1
aux = p[i]
p[i] = p[k]
p[k] = aux
for j in range(1,(n-i)/2+1):
aux = p[i+j]
p[i+j] = p[n-j+1]
p[n-j+1] = aux
break

perm(5)
``````

Here is an algorithm that works on a list without creating new intermediate lists similar to Ber's solution at https://stackoverflow.com/a/108651/184528.

``````def permute(xs, low=0):
if low + 1 >= len(xs):
yield xs
else:
for p in permute(xs, low + 1):
yield p
for i in range(low + 1, len(xs)):
xs[low], xs[i] = xs[i], xs[low]
for p in permute(xs, low + 1):
yield p
xs[low], xs[i] = xs[i], xs[low]

for p in permute([1, 2, 3, 4]):
print p
``````

You can try the code out for yourself here: http://repl.it/J9v

This algorithm is the most effective one, it avoids of array passing and manipulation in recursive calls, works in Python 2, 3:

``````def permute(items):
length = len(items)
def inner(ix=[]):
do_yield = len(ix) == length - 1
for i in range(0, length):
if i in ix: #avoid duplicates
continue
if do_yield:
yield tuple([items[y] for y in ix + [i]])
else:
for p in inner(ix + [i]):
yield p
return inner()
``````

Usage:

``````for p in permute((1,2,3)):
print(p)

(1, 2, 3)
(1, 3, 2)
(2, 1, 3)
(2, 3, 1)
(3, 1, 2)
(3, 2, 1)
``````
``````def pzip(c, seq):
result = []
for item in seq:
for i in range(len(item)+1):
result.append(item[i:]+c+item[:i])
return result

def perm(line):
seq = [c for c in line]
if len(seq) <=1 :
return seq
else:
return pzip(seq[0], perm(seq[1:]))
``````

Generate all possible permutations

I'm using python3.4:

``````def calcperm(arr, size):
result = set([()])
for dummy_idx in range(size):
temp = set()
for dummy_lst in result:
for dummy_outcome in arr:
if dummy_outcome not in dummy_lst:
new_seq = list(dummy_lst)
new_seq.append(dummy_outcome)
result = temp
return result
``````

Test Cases:

``````lst = [1, 2, 3, 4]
#lst = ["yellow", "magenta", "white", "blue"]
seq = 2
final = calcperm(lst, seq)
print(len(final))
print(final)
``````
• This (so far) is the most understandable solution for me (non-math head). I can list chars I want to permutate and this works! What is the logic to add duplicates characters to permutations? Example: `def calcperm(arr, size, dupes):` where `dupes` are the allowed numbers of duplicates to allow for each permutation. Nov 10, 2021 at 4:35

I see a lot of iteration going on inside these recursive functions, not exactly pure recursion...

so for those of you who cannot abide by even a single loop, here's a gross, totally unnecessary fully recursive solution

``````def all_insert(x, e, i=0):
return [x[0:i]+[e]+x[i:]] + all_insert(x,e,i+1) if i<len(x)+1 else []

def for_each(X, e):
return all_insert(X[0], e) + for_each(X[1:],e) if X else []

def permute(x):
return [x] if len(x) < 2 else for_each( permute(x[1:]) , x[0])

perms = permute([1,2,3])
``````

To save you folks possible hours of searching and experimenting, here's the non-recursive permutaions solution in Python which also works with Numba (as of v. 0.41):

``````@numba.njit()
def permutations(A, k):
r = [[i for i in range(0)]]
for i in range(k):
r = [[a] + b for a in A for b in r if (a in b)==False]
return r
permutations([1,2,3],3)
[[1, 2, 3], [1, 3, 2], [2, 1, 3], [2, 3, 1], [3, 1, 2], [3, 2, 1]]
``````

To give an impression about performance:

``````%timeit permutations(np.arange(5),5)

243 µs ± 11.1 µs per loop (mean ± std. dev. of 7 runs, 1 loop each)
time: 406 ms

%timeit list(itertools.permutations(np.arange(5),5))
15.9 µs ± 8.61 ns per loop (mean ± std. dev. of 7 runs, 100000 loops each)
time: 12.9 s
``````

So use this version only if you have to call it from njitted function, otherwise prefer itertools implementation.

Anyway we could use sympy library , also support for multiset permutations

``````import sympy
from sympy.utilities.iterables import multiset_permutations
t = [1,2,3]
p = list(multiset_permutations(t))
print(p)

# [[1, 2, 3], [1, 3, 2], [2, 1, 3], [2, 3, 1], [3, 1, 2], [3, 2, 1]]
``````

Answer is highly inspired by Get all permutations of a numpy array

Another solution:

``````def permutation(flag, k =1 ):
N = len(flag)
for i in xrange(0, N):
if flag[i] != 0:
continue
flag[i] = k
if k == N:
print flag
permutation(flag, k+1)
flag[i] = 0

permutation([0, 0, 0])
``````
• NameError: name 'xrange' is not defined Apr 4, 2021 at 20:20
• @Pathros well, the code above is for Python 2. For Python 3, please use `range()`. See stackoverflow.com/questions/17192158/… Apr 6, 2021 at 10:13

This is the asymptotically optimal way O(n*n!) of generating permutations after initial sorting.

There are n! permutations at most and hasNextPermutation(..) runs in O(n) time complexity

In 3 steps,

1. Find largest j such that a[j] can be increased
2. Increase a[j] by smallest feasible amount
3. Find lexicogrpahically least way to extend the new a[0..j]
``````'''
Lexicographic permutation generation

consider example array state of [1,5,6,4,3,2] for sorted [1,2,3,4,5,6]
after 56432(treat as number) ->nothing larger than 6432(using 6,4,3,2) beginning with 5
so 6 is next larger and 2345(least using numbers other than 6)
so [1, 6,2,3,4,5]
'''
def hasNextPermutation(array, len):
' Base Condition '
if(len ==1):
return False
'''
Set j = last-2 and find first j such that a[j] < a[j+1]
If no such j(j==-1) then we have visited all permutations
after this step a[j+1]>=..>=a[len-1] and a[j]<a[j+1]

a[j]=5 or j=1, 6>5>4>3>2
'''
j = len -2
while (j >= 0 and array[j] >= array[j + 1]):
j= j-1
if(j==-1):
return False
# print(f"After step 2 for j {j}  {array}")
'''
decrease l (from n-1 to j) repeatedly until a[j]<a[l]
Then swap a[j], a[l]
a[l] is the smallest element > a[j] that can follow a[l]...a[j-1] in permutation
before swap we have a[j+1]>=..>=a[l-1]>=a[l]>a[j]>=a[l+1]>=..>=a[len-1]
after swap -> a[j+1]>=..>=a[l-1]>=a[j]>a[l]>=a[l+1]>=..>=a[len-1]

a[l]=6 or l=2, j=1 just before swap [1, 5, 6, 4, 3, 2]
after swap [1, 6, 5, 4, 3, 2] a[l]=5, a[j]=6
'''
l = len -1
while(array[j] >= array[l]):
l = l-1
# print(f"After step 3 for l={l}, j={j} before swap {array}")
array[j], array[l] = array[l], array[j]
# print(f"After step 3 for l={l} j={j} after swap {array}")
'''
Reverse a[j+1...len-1](both inclusive)

after reversing [1, 6, 2, 3, 4, 5]
'''
array[j+1:len] = reversed(array[j+1:len])
# print(f"After step 4 reversing {array}")
return True

array = [1,2,4,4,5]
array.sort()
len = len(array)
count =1
print(array)
'''
The algorithm visits every permutation in lexicographic order
generating one by one
'''
while(hasNextPermutation(array, len)):
print(array)
count = count +1
# The number of permutations will be n! if no duplicates are present, else less than that
# [1,4,3,3,2] -> 5!/2!=60
print(f"Number of permutations: {count}")

``````