# Generate all permutations of cyclic shift of length K in a list of length N efficiently

How can I generate all permutations of cyclic shifts of length k in a list of length n. Here shift is cyclic and right. Notice that:

if K==1 , there's no shift. Hence, no permutation of those 0 shifts.
if K==2 , this is equivalent to swapping the elements. Hence all n! permutations can be generated.

eg. if list is [1 4 2],K=2 (thus from 0 to N-K, loop)

``````P1: [1,4,2] #Original list. No shift.
P2: [4,1,2] #Shift from 0 of [1,4,2]
P3: [4,2,1] #Shift from 1 of [4,1,2] as 0 gives P1
P4: [2,4,1] #Shift from 0 of [4,2,1]
P5: [2,1,4] #Shift from 1 of [1,4,2] as 0 of P4=P3
P6: [1,2,4] #Shift from 0 of [2,1,4]
``````

if K==3, things get interesting as some permutations are left out.

eg. if list=[1,3,4,2],K=3 ( thus from index 0 to 4-3,loop)

``````P1 : [1,3,4,2] #Original list. No shift.
P2 : [4,1,3,2] #Shift from 0th of [1,3,4,2]
P3 : [3,4,1,2] #Shift from 0th of [4,1,3,2]
P4 : [3,2,4,1] #Shift from 1th of [3,4,1,2] as 0th gives P1
P5 : [4,3,2,1] #Shift from 0th of [3,2,4,1]
P6 : [2,4,3,1] #Shift from 0th of [4,3,2,1]
P7 : [2,1,4,3] #Shift from 1th of [2,4,3,1] as 0th gives P3
P8 : [4,2,1,3] #Shift from 0th of [2,1,4,3]
P9 : [1,4,2,3] #Shift from 0th of [4,2,1,3]
P10: [2,3,1,4] #Shift from 1th of [2,1,4,3] as 0 from P9=P7,1 from P9=P1,1 from P8=P5
P11: [1,2,3,4] #Shift from 0th of [2,3,1,4]
P12: [3,1,2,4] #Shift from 0th of [1,2,3,4]

#Now,all have been generated, as moving further will lead to previously found values.
``````

Notice,that these permutations are half (12) of what should've been (24). To, implement this, algorithm, I am currently using backtracking. Here's what I have tried so far (in Python)

``````def get_possible_cyclic(P,N,K,stored_perms): #P is the original list
from collections import deque

if P in stored_perms:
return    #Backtracking to the previous

stored_perms.append(P)

for start in xrange(N-K+1):
"""
Shifts cannot wrap around. Eg. 1,2,3,4 ,K=3
Recur for  (1,2,3),4 or 1,(2,3,4) where () denotes the cycle
"""
l0=P[:start]                    #Get all elements that are before cycle ranges
l1=deque(P[start:K+start])      #Get the elements we want in cycle
l1.rotate()                     #Form their cycle
l2=P[K+start:]                  #Get all elements after cycle ranges

l=l0+list(l1)+l2                #Form the required list
get_possible_cyclic(l,N,K,stored_perms)

for index,i in enumerate(stored_perms):
print i,index+1

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

This produces the output

``````[1, 3, 4, 2] 1
[4, 1, 3, 2] 2
[3, 4, 1, 2] 3
[3, 2, 4, 1] 4
[4, 3, 2, 1] 5
[2, 4, 3, 1] 6
[2, 1, 4, 3] 7
[4, 2, 1, 3] 8
[1, 4, 2, 3] 9
[2, 3, 1, 4] 10
[1, 2, 3, 4] 11
[3, 1 ,2, 4] 12

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

This is exactly what I want, but a lot lot slower,since here the recursion depth exceeds for N>7. I hope, I have explained myself clearly. Anyone, with any optimizations?

• Try starting with increasing integers: 1,2 then 1,2,3 and lastly 1,2,3,4 - check correct answers by hand, then look for patterns in the result. – Paddy3118 Oct 6 '15 at 6:52
• I gather that you're trying to solve the problem PERSHFTS from an ongoing CodeChef contest. Enumeration will not help you here. – David Eisenstat Oct 6 '15 at 12:32
• Haha, Yes I know. That's simple parity check for a permutation and printing its lexicographic index/2. I was just keen on improving my original approach, since I always start from brute and optimize as I go on. Thanks, for your tip though. – Aman Garg Oct 6 '15 at 21:19

The check

``````if P in stored_perms:
``````

gets slower and slower as `stored_perms` grows, because it requires comparing `P` with the elements of `stored_perms` one at a time, until either a copy is found or the end of the list is encountered. Since every permutation will be added to `stored_perms` once, the number of comparisons with `P` is at least quadratic in the number of permutations found, which will generally be either all the possible permutations or half of them, depending on whether k is even or odd (assuming 1 < k < N).

It's a lot more efficient to use a set. Python's set is based on a hash-table, so the membership check is usually O(1) rather than O(N). However, there are a couple of limitations:

1. The elements added to the set need to be hashable, and Python lists are not hashable. Fortunately, tuples are hashable, so a small change fixes the issue.

2. Iterating over a set is unpredictable. In particular, you cannot reliably modify the set while you are iterating over it.

In addition to changing P to a tuple and stored_perms to a set, it's worthwhile considering search based on a workqueue instead of a recursive search. I don't know if it will be any faster, but it avoids any issues with recursion depth.

Putting all that together, I threw the following together:

``````def get_cyclics(p, k):
found = set()      # set of tuples we have seen so far
todo = [tuple(p)]  # list of tuples we still need to explore
n = len(p)
while todo:
x = todo.pop()
for i in range(n - k + 1):
perm = ( x[:i]                    # Prefix
+ x[i+1:i+k] + x[i:i+1]    # Rotated middle
+ x[i+k:]                  # Suffix
)
if perm not in found: