For instance, I have lists:

a[0] = [1, 1, 1, 0, 0]
a[1] = [1, 1, 0, 0, 1]
a[2] = [0, 1, 1, 1, 0]
# and so on

They seem to be different, but if it is supposed that the start and the end are connected, then they are circularly identical.

The problem is, each list which I have has a length of 55 and contains only three ones and 52 zeros in it. Without circular condition, there are 26,235 (55 choose 3) lists. However, if the condition 'circular' exists, there are a huge number of circularly identical lists

Currently I check circularly identity by following:

def is_dup(a, b):
    for i in range(len(a)):
        if a == list(numpy.roll(b, i)): # shift b circularly by i
            return True
    return False

This function requires 55 cyclic shift operations at the worst case. And there are 26,235 lists to be compared with each other. In short, I need 55 * 26,235 * (26,235 - 1) / 2 = 18,926,847,225 computations. It's about nearly 20 Giga!

Is there any good way to do it with less computations? Or any data types that supports circular?

  • Just a hunch : I feel that suffix trees might help here. en.wikipedia.org/wiki/Suffix_tree . To build one, see en.wikipedia.org/wiki/Ukkonen%27s_algorithm
    – Rerito
    Nov 14, 2014 at 7:21
  • 1
    @Mehrdad But far worse running time than any answer that converts to a canonical form, far worse running time than converting to an integer and far, far worse running time than David Eisenstat's.
    – Veedrac
    Nov 15, 2014 at 14:56
  • 2
    All of answers trying to solve general problem, but in this particular case with only 3 ones you can represent every list with 3 numbers being a number of zeros between ones. List from question can be represented as [0,0,2], [0,2,0], [2,0,0]. You can simply reduce list in one run and then check reduced list. If they are "circularly identical" then originals are too.
    – abc667
    Nov 15, 2014 at 19:09
  • 2
    I guess Stack Overflow doesn't need voting then. All we need is to run the code in all the solutions, and present them in the order in which they finish. Nov 17, 2014 at 2:19
  • 2
    Since it hasn't been mentioned so far, the "canonical form" referred to by @abc667, Veedrac, and Eisenstat is called Run Length Encoding en.wikipedia.org/wiki/Run-length_encoding Nov 18, 2014 at 22:37

18 Answers 18


First off, this can be done in O(n) in terms of the length of the list You can notice that if you will duplicate your list 2 times ([1, 2, 3]) will be [1, 2, 3, 1, 2, 3] then your new list will definitely hold all possible cyclic lists.

So all you need is to check whether the list you are searching is inside a 2 times of your starting list. In python you can achieve this in the following way (assuming that the lengths are the same).

list1 = [1, 1, 1, 0, 0]
list2 = [1, 1, 0, 0, 1]
print ' '.join(map(str, list2)) in ' '.join(map(str, list1 * 2))

Some explanation about my oneliner: list * 2 will combine a list with itself, map(str, [1, 2]) convert all numbers to string and ' '.join() will convert array ['1', '2', '111'] into a string '1 2 111'.

As pointed by some people in the comments, oneliner can potentially give some false positives, so to cover all the possible edge cases:

def isCircular(arr1, arr2):
    if len(arr1) != len(arr2):
        return False

    str1 = ' '.join(map(str, arr1))
    str2 = ' '.join(map(str, arr2))
    if len(str1) != len(str2):
        return False

    return str1 in str2 + ' ' + str2

P.S.1 when speaking about time complexity, it is worth noticing that O(n) will be achieved if substring can be found in O(n) time. It is not always so and depends on the implementation in your language (although potentially it can be done in linear time KMP for example).

P.S.2 for people who are afraid strings operation and due to this fact think that the answer is not good. What important is complexity and speed. This algorithm potentially runs in O(n) time and O(n) space which makes it much better than anything in O(n^2) domain. To see this by yourself, you can run a small benchmark (creates a random list pops the first element and appends it to the end thus creating a cyclic list. You are free to do your own manipulations)

from random import random
bigList = [int(1000 * random()) for i in xrange(10**6)]
bigList2 = bigList[:]

# then test how much time will it take to come up with an answer
from datetime import datetime
startTime = datetime.now()
print isCircular(bigList, bigList2)
print datetime.now() - startTime    # please fill free to use timeit, but it will give similar results

0.3 seconds on my machine. Not really long. Now try to compare this with O(n^2) solutions. While it is comparing it, you can travel from US to Australia (most probably by a cruise ship)

  • 3
    Just adding padding spaces (1 before and 1 after each string) will do the trick. No need to overcomplicate things with regexes. (Of course I'm assuming we compare lists of the same length)
    – Rerito
    Nov 14, 2014 at 7:32
  • 2
    @Rerito unless either list includes strings, which may themselves have leading or trailing spaces. Still can cause collisions.
    – Adam Smith
    Nov 14, 2014 at 7:39
  • 12
    I don't like this answer. The string operation nonsense made me dislike it and David Eisenstat's answer made me willing to downvote it. This comparison can be done in O(n) time with a string but it also can be done in O(n) time with an integer [need 10k as self-deleted], which is faster. Nonetheless, David Eisenstat's answer shows that doing any comparisons at all is pointless since the answer doesn't need it.
    – Veedrac
    Nov 14, 2014 at 18:42
  • 7
    @Veedrac are you kidding me? Have you heard about computational complexity? Davids answer takes O(n^2) time and O(n^2) space just to generate all his repetitions which even for small inputs 10^4 length takes like 22 seconds and who knows how much ram. Not to mention that we have not started to search for anything right now (we just generated all cyclic rotations). And my string nonsense gives you a complete result for inputs like 10^6 in less than 0.5 seconds. It also needs O(n) space to store it. So please take some time understanding the answer before jumping into conclusion. Nov 14, 2014 at 23:10
  • 1
    @SalvadorDali You seem very (soft) time focused ;-)
    – Déjà vu
    Nov 17, 2014 at 0:31

Not knowledgeable enough in Python to answer this in your requested language, but in C/C++, given the parameters of your question, I'd convert the zeros and ones to bits and push them onto the least significant bits of an uint64_t. This will allow you to compare all 55 bits in one fell swoop - 1 clock.

Wickedly fast, and the whole thing will fit in on-chip caches (209,880 bytes). Hardware support for shifting all 55 list members right simultaneously is available only in a CPU's registers. The same goes for comparing all 55 members simultaneously. This allows for a 1-for-1 mapping of the problem to a software solution. (and using the SIMD/SSE 256 bit registers, up to 256 members if needed) As a result the code is immediately obvious to the reader.

You might be able to implement this in Python, I just don't know it well enough to know if that's possible or what the performance might be.

After sleeping on it a few things became obvious, and all for the better.

1.) It's so easy to spin the circularly linked list using bits that Dali's very clever trick isn't necessary. Inside a 64-bit register standard bit shifting will accomplish the rotation very simply, and in an attempt to make this all more Python friendly, by using arithmetic instead of bit ops.

2.) Bit shifting can be accomplished easily using divide by 2.

3.) Checking the end of the list for 0 or 1 can be easily done by modulo 2.

4.) "Moving" a 0 to the head of the list from the tail can be done by dividing by 2. This because if the zero were actually moved it would make the 55th bit false, which it already is by doing absolutely nothing.

5.) "Moving" a 1 to the head of the list from the tail can be done by dividing by 2 and adding 18,014,398,509,481,984 - which is the value created by marking the 55th bit true and all the rest false.

6.) If a comparison of the anchor and composed uint64_t is TRUE after any given rotation, break and return TRUE.

I would convert the entire array of lists into an array of uint64_ts right up front to avoid having to do the conversion repeatedly.

After spending a few hours trying to optimize the code, studying the assembly language I was able to shave 20% off the runtime. I should add that the O/S and MSVC compiler got updated mid-day yesterday as well. For whatever reason/s, the quality of the code the C compiler produced improved dramatically after the update (11/15/2014). Run-time is now ~ 70 clocks, 17 nanoseconds to compose and compare an anchor ring with all 55 turns of a test ring and NxN of all rings against all others is done in 12.5 seconds.

This code is so tight all but 4 registers are sitting around doing nothing 99% of the time. The assembly language matches the C code almost line for line. Very easy to read and understand. A great assembly project if someone were teaching themselves that.

Hardware is Hazwell i7, MSVC 64-bit, full optimizations.

#include "stdafx.h"
#include "stdafx.h"
#include <string>
#include <memory>
#include <stdio.h>
#include <time.h>

const uint8_t  LIST_LENGTH = 55;    // uint_8 supports full witdth of SIMD and AVX2
// max left shifts is 32, so must use right shifts to create head_bit
const uint64_t head_bit = (0x8000000000000000 >> (64 - LIST_LENGTH)); 
const uint64_t CPU_FREQ = 3840000000;   // turbo-mode clock freq of my i7 chip

const uint64_t LOOP_KNT = 688275225; // 26235^2 // 1000000000;

// ----------------------------------------------------------------------------
__inline uint8_t is_circular_identical(const uint64_t anchor_ring, uint64_t test_ring)
    // By trial and error, try to synch 2 circular lists by holding one constant
    //   and turning the other 0 to LIST_LENGTH positions. Return compare count.

    // Return the number of tries which aligned the circularly identical rings, 
    //  where any non-zero value is treated as a bool TRUE. Return a zero/FALSE,
    //  if all tries failed to find a sequence match. 
    // If anchor_ring and test_ring are equal to start with, return one.

    for (uint8_t i = LIST_LENGTH; i;  i--)
        // This function could be made bool, returning TRUE or FALSE, but
        // as a debugging tool, knowing the try_knt that got a match is nice.
        if (anchor_ring == test_ring) {  // test all 55 list members simultaneously
            return (LIST_LENGTH +1) - i;

        if (test_ring % 2) {    //  ring's tail is 1 ?
            test_ring /= 2;     //  right-shift 1 bit
            // if the ring tail was 1, set head to 1 to simulate wrapping
            test_ring += head_bit;      
        }   else    {           // ring's tail must be 0
            test_ring /= 2;     // right-shift 1 bit
            // if the ring tail was 0, doing nothing leaves head a 0
    // if we got here, they can't be circularly identical
    return 0;
// ----------------------------------------------------------------------------
    int main(void)  {
        time_t start = clock();
        uint64_t anchor, test_ring, i,  milliseconds;
        uint8_t try_knt;

        anchor = 31525197391593472; // bits 55,54,53 set true, all others false
        // Anchor right-shifted LIST_LENGTH/2 represents the average search turns
        test_ring = anchor >> (1 + (LIST_LENGTH / 2)); //  117440512; 

        printf("\n\nRunning benchmarks for %llu loops.", LOOP_KNT);
        start = clock();
        for (i = LOOP_KNT; i; i--)  {
            try_knt = is_circular_identical(anchor, test_ring);
            // The shifting of test_ring below is a test fixture to prevent the 
            //  optimizer from optimizing the loop away and returning instantly
            if (i % 2) {
                test_ring /= 2;
            }   else  {
                test_ring *= 2;
        milliseconds = (uint64_t)(clock() - start);
        printf("\nET for is_circular_identical was %f milliseconds."
                "\n\tLast try_knt was %u for test_ring list %llu", 
                        (double)milliseconds, try_knt, test_ring);

        printf("\nConsuming %7.1f clocks per list.\n",
                (double)((milliseconds * (CPU_FREQ / 1000)) / (uint64_t)LOOP_KNT));

        return 0;

enter image description here

  • 24
    people keep talking about "salvador dali's solution" and i was just sitting here confused, wondering if the painter of the same name was also a mathematician who contributed to classical algorithms in some significant way. then i realized that's the username of the person who posted the most popular answer. i am not a smart man. Nov 14, 2014 at 20:26
  • For anyone with 10k rep, and implementation is available here using Numpy and vectorization. Gist mirror for those <10k. I deleted my answer because David Eisenstat's answer points out that you don't need to do comparisons at all as you can just generate the unique lists straight away and I want to encourage people to use his far better answer.
    – Veedrac
    Nov 14, 2014 at 21:11
  • @RocketRoy Why do you think Python wouldn't have bit operations? Heck, I use bit operations in the code I linked. I still think this answer is mostly unneeded (David Eisenstat's answer takes 1ms for the whole thing), but I found that statement strange. FWIW, a similar algorithm in Numpy for searching 262M-"lists" takes about 15s on my computer (assuming no match is found), only the rotating of the list happens in the outer loop, not the inner one.
    – Veedrac
    Nov 15, 2014 at 5:55
  • @Quincunx, thank you for your edit to get the syntax coloring correct for C++. Greatly appreciated!
    – user1899861
    Nov 17, 2014 at 0:22
  • @RocketRoy No problem. When you answer a lot of questions over on PPCG, you learn how to do the syntax coloring.
    – Justin
    Nov 17, 2014 at 0:47

Reading between the lines, it sounds as though you're trying to enumerate one representative of each circular equivalence class of strings with 3 ones and 52 zeros. Let's switch from a dense representation to a sparse one (set of three numbers in range(55)). In this representation, the circular shift of s by k is given by the comprehension set((i + k) % 55 for i in s). The lexicographic minimum representative in a class always contains the position 0. Given a set of the form {0, i, j} with 0 < i < j, the other candidates for minimum in the class are {0, j - i, 55 - i} and {0, 55 - j, 55 + i - j}. Hence, we need (i, j) <= min((j - i, 55 - i), (55 - j, 55 + i - j)) for the original to be minimum. Here's some enumeration code.

def makereps():
    reps = []
    for i in range(1, 55 - 1):
        for j in range(i + 1, 55):
            if (i, j) <= min((j - i, 55 - i), (55 - j, 55 + i - j)):
                reps.append('1' + '0' * (i - 1) + '1' + '0' * (j - i - 1) + '1' + '0' * (55 - j - 1))
    return reps
  • 2
    @SalvadorDali You've misunderstood the answer (I did so too until he pointed it out!). This directly generates "one representative of each circular equivalence class of strings with 3 ones and 52 zeros". His code doesn't generate all cyclical rotations. The original cost¹ is T(55²·26235²). Your code improves the 55² to 55, so is just T(55*26235²). David Eisenstat's answer is between 55² and 55³ for the whole thing. 55³ ≪ 55·26235². ¹Not talking big-O terms here as the actual cost in O(1) in all cases.
    – Veedrac
    Nov 14, 2014 at 23:55
  • 1
    @Veedrac But 99% of readers who will come to this question in the future, will not have his constrains and I believe my answer will suit them better. Without bloating the conversation further I will leave to the OP to explain what exactly does he want. Nov 15, 2014 at 0:18
  • 5
    @SalvadorDali OP appears to have fallen prey to the XY Problem. Fortunately, the question itself makes clear what the title does not, and David was able to read between the lines. If this is in fact the case, then the right thing to do is to alter the title and solve the actual problem, rather than to answer the title and ignore the question. Nov 15, 2014 at 1:06
  • 1
    @SalvadorDali, under the covers your Python code is calling the equivalent of C's strstr() which searches a string for a sub-string. That in turn calls strcmp(), which runs a for() loop comparing each char in a string1 with string2. Therefore, what looks like O(n) is O(n*55*55) assuming a search to failure. High level languages are a 2-edged sword. They hide implementation details from you, but then they also hide implementation details from you. FWIW, your insight to concatenate the list was brilliant. Faster still as uint8, and much faster as bits - which can be easily rotated in hardware.
    – user1899861
    Nov 19, 2014 at 3:28
  • 2
    @AleksandrDubinsky Simpler for the computer, more complicated for human beings. It's fast enough as is. Nov 19, 2014 at 16:22

Repeat the first array, then use the Z algorithm (O(n) time) to find the second array inside the first.

(Note: you don't have to physically copy the first array. You can just wrap around during matching.)

The nice thing about the Z algorithm is that it's very simple compared to KMP, BM, etc.
However, if you're feeling ambitious, you could do string matching in linear time and constant space -- strstr, for example, does this. Implementing it would be more painful, though.


Following up on Salvador Dali's very smart solution, the best way to handle it is to make sure all elements are of the same length, as well as both LISTS are of the same length.

def is_circular_equal(lst1, lst2):
    if len(lst1) != len(lst2):
        return False
    lst1, lst2 = map(str, lst1), map(str, lst2)
    len_longest_element = max(map(len, lst1))
    template = "{{:{}}}".format(len_longest_element)
    circ_lst = " ".join([template.format(el) for el in lst1]) * 2
    return " ".join([template.format(el) for el in lst2]) in circ_lst

No clue if this is faster or slower than AshwiniChaudhary's recommended regex solution in Salvador Dali's answer, which reads:

import re

def is_circular_equal(lst1, lst2):
    if len(lst2) != len(lst2):
        return False
    return bool(re.search(r"\b{}\b".format(' '.join(map(str, lst2))),
                          ' '.join(map(str, lst1)) * 2))
  • 1
    wiki'd this since I basically just tweaked Salvador Dali's answer and formatted Ashwini's changes. Very little of this is actually mine.
    – Adam Smith
    Nov 14, 2014 at 7:38
  • 1
    thank you for the input. I think I covered all the possible cases in my edited solution. Let me know if something is missing. Nov 14, 2014 at 7:42
  • @SalvadorDali ah, yes...checking that the strings are the same length. I SUPPOSE that would be easier than running through the list looking for the longest element, then calling str.format n times to format the resulting string. I SUPPOSE.... :)
    – Adam Smith
    Nov 14, 2014 at 7:44

Given that you need to do so many comparisons might it be worth your while taking an initial pass through your lists to convert them into some sort of canonical form that can be easily compared?

Are you trying to get a set of circularly-unique lists? If so you can throw them into a set after converting to tuples.

def normalise(lst):
    # Pick the 'maximum' out of all cyclic options
    return max([lst[i:]+lst[:i] for i in range(len(lst))])

a_normalised = map(normalise,a)
a_tuples = map(tuple,a_normalised)
a_unique = set(a_tuples)

Apologies to David Eisenstat for not spotting his v.similar answer.


You can roll one list like this:

list1, list2 = [0,1,1,1,0,0,1,0], [1,0,0,1,0,0,1,1]


def rotate(string_to_rotate, result=[]):
    for i in xrange(1,len(string_to_rotate)):
    return result

for x in rotate(str_list1):
    if cmp(x,str_list2)==0:
        print "lists are rotationally identical"

First convert every of your list elements (in a copy if necessary) to that rotated version that is lexically greatest.

Then sort the resulting list of lists (retaining an index into the original list position) and unify the sorted list, marking all the duplicates in the original list as needed.


Piggybacking on @SalvadorDali's observation on looking for matches of a in any a-lengthed sized slice in b+b, here is a solution using just list operations.

def rollmatch(a,b):
    return any(not any(ax^bbx for ax,bbx in zip(a,bb[i:])) for i in range(len(a)))

l1 = [1,0,0,1]
l2 = [1,1,0,0]
l3 = [1,0,1,0]

rollmatch(l1,l2)  # True
rollmatch(l1,l3)  # False

2nd approach: [deleted]

  • First version is O(n²) and second doesn't work for rollmatch([1, 0, 1, 1], [0, 1, 1, 1]).
    – Veedrac
    Nov 14, 2014 at 16:44
  • Nice catch, I'll delete it!
    – PaulMcG
    Nov 14, 2014 at 18:56

Not a complete, free-standing answer, but on the topic of optimizing by reducing comparisons, I too was thinking of normalized representations.

Namely, if your input alphabet is {0, 1}, you could reduce the number of allowed permutations significantly. Rotate the first list to a (pseudo-) normalized form (given the distribution in your question, I would pick one where one of the 1 bits is on the extreme left, and one of the 0 bits is on the extreme right). Now before each comparison, successively rotate the other list through the possible positions with the same alignment pattern.

For example, if you have a total of four 1 bits, there can be at most 4 permutations with this alignment, and if you have clusters of adjacent 1 bits, each additional bit in such a cluster reduces the amount of positions.

List 1   1 1 1 0 1 0

List 2   1 0 1 1 1 0  1st permutation
         1 1 1 0 1 0  2nd permutation, final permutation, match, done

This generalizes to larger alphabets and different alignment patterns; the main challenge is to find a good normalization with only a few possible representations. Ideally, it would be a proper normalization, with a single unique representation, but given the problem, I don't think that's possible.


Building further on RocketRoy's answer: Convert all your lists up front to unsigned 64 bit numbers. For each list, rotate those 55 bits around to find the smallest numerical value.

You are now left with a single unsigned 64 bit value for each list that you can compare straight with the value of the other lists. Function is_circular_identical() is not required anymore.

(In essence, you create an identity value for your lists that is not affected by the rotation of the lists elements) That would even work if you have an arbitrary number of one's in your lists.


This is the same idea of Salvador Dali but don't need the string convertion. Behind is the same KMP recover idea to avoid impossible shift inspection. Them only call KMPModified(list1, list2+list2).

    public class KmpModified
        public int[] CalculatePhi(int[] pattern)
            var phi = new int[pattern.Length + 1];
            phi[0] = -1;
            phi[1] = 0;

            int pos = 1, cnd = 0;
            while (pos < pattern.Length)
                if (pattern[pos] == pattern[cnd])
                    phi[pos + 1] = cnd;
                else if (cnd > 0)
                    cnd = phi[cnd];
                    phi[pos + 1] = 0;

            return phi;

        public IEnumerable<int> Search(int[] pattern, int[] list)
            var phi = CalculatePhi(pattern);

            int m = 0, i = 0;
            while (m < list.Length)
                if (pattern[i] == list[m])
                    if (i == pattern.Length)
                        yield return m - i + 1;
                        i = phi[i];
                else if (i > 0)
                    i = phi[i];
                    i = 0;

        public void BasicTest()
            var pattern = new[] { 1, 1, 10 };
            var list = new[] {2, 4, 1, 1, 1, 10, 1, 5, 1, 1, 10, 9};
            var matches = Search(pattern, list).ToList();

            Assert.Equal(new[] {3, 8}, matches);

        public void SolveProblem()
            var random = new Random();
            var list = new int[10];
            for (var k = 0; k < list.Length; k++)
                list[k]= random.Next();

            var rotation = new int[list.Length];
            for (var k = 1; k < list.Length; k++)
                rotation[k - 1] = list[k];
            rotation[rotation.Length - 1] = list[0];

            Assert.True(Search(list, rotation.Concat(rotation).ToArray()).Any());

Hope this help!


Simplifying The Problem

  • The problem consist of list of ordered items
  • The domain of value is binary (0,1)
  • We can reduce the problem by mapping consecutive 1s into a count
  • and consecutive 0s into a negative count


A = [ 1, 1, 1, 0, 0, 1, 1, 0 ]
B = [ 1, 1, 0, 1, 1, 1, 0, 0 ]
A = [ +3, -2, +2, -1 ]
B = [ +2, -1, +3, -2 ]
  • This process require that the first item and the last item must be different
  • This will reduce the amount of comparisons overall

Checking Process

  • If we assume that they're duplicate, then we can assume what we are looking for
  • Basically the first item from the first list must exist somewhere in the other list
  • Followed by what is followed in the first list, and in the same manner
  • The previous items should be the last items from the first list
  • Since it's circular, the order is the same

The Grip

  • The question here is where to start, technically known as lookup and look-ahead
  • We will just check where the first element of the first list exist through the second list
  • The probability of frequent element is lower given that we mapped the lists into histograms







    END IF




                RETURN TRUE

            END IF

        END IF





    INTEGER I = 0


        IF L1[I] != L2[(INDEX+I)%L2.SIZE] THEN

            RETURN FALSE

        END IF

        I = I + 1










If the list size is going to be pretty huge or if the element we are starting to check the cycle from is frequently high, then we can do the following:

  • Look for the least-frequent item in the first list to start with

  • increase the n-gram N parameter to lower the probability of going through a the linear check


An efficient, quick-to-compute "canonical form" for the lists in question can be derived as:

  • Count the number of zeroes between the ones (ignoring wrap-around), to get three numbers.
  • Rotate the three numbers so that the biggest number is first.
  • The first number (a) must be between 18 and 52 (inclusive). Re-encode it as between 0 and 34.
  • The second number (b) must be between 0 and 26, but it doesn't matter much.
  • Drop the third number, since it's just 52 - (a + b) and adds no information

The canonical form is the integer b * 35 + a, which is between 0 and 936 (inclusive), which is fairly compact (there are 477 circularly-unique lists in total).


I wrote an straightforward solution which compares both lists and just increases (and wraps around) the index of the compared value for each iteration.

I don't know python well so I wrote it in Java, but it's really simple so it should be easy to adapt it to any other language.

By this you could also compare lists of other types.

public class Main {

    public static void main(String[] args){
        int[] a = {0,1,1,1,0};
        int[] b = {1,1,0,0,1};

        System.out.println(isCircularIdentical(a, b));

    public static boolean isCircularIdentical(int[] a, int[]b){
        if(a.length != b.length){
            return false;

        //The outer loop is for the increase of the index of the second list
        for(int i = 0; i < a.length; i++){
            //Loop trough the list and compare each value to the according value of the second list
            for(int k = 0; k < a.length; k++){
                // I use modulo length to wrap around the index
                if(a[k] != b[(k + i) % a.length]){
                    //If the values do not match I continue and shift the index one further
                    continue outer;
            return true;
        return false;

As others have mentioned, once you find the normalized rotation of a list, you can compare them.

Heres some working code that does this, Basic method is to find a normalized rotation for each list and compare:

  • Calculate a normalized rotation index on each list.
  • Loop over both lists with their offsets, comparing each item, returning if they mis-match.

Note that this method is it doesn't depend on numbers, you can pass in lists of strings (any values which can be compared).

Instead of doing a list-in-list search, we know we want the list to start with the minimum value - so we can loop over the minimum values, searching until we find which one has the lowest successive values, storing this for further comparisons until we have the best.

There are many opportunities to exit early when calculating the index, details on some optimizations.

  • Skip searching for the best minimum value when theres only one.
  • Skip searching minimum values when the previous is also a minimum value (it will never be a better match).
  • Skip searching when all values are the same.
  • Fail early when lists have different minimum values.
  • Use regular comparison when offsets match.
  • Adjust offsets to avoid wrapping the index values on one of the lists during comparison.

Note that in Python a list-in-list search may well be faster, however I was interested to find an efficient algorithm - which could be used in other languages too. Also, there is some advantage to avoiding to create new lists.

def normalize_rotation_index(ls, v_min_other=None):
    """ Return the index or -1 (when the minimum is above `v_min_other`) """

    if len(ls) <= 1:
        return 0

    def compare_rotations(i_a, i_b):
        """ Return True when i_a is smaller.
            Note: unless there are large duplicate sections of identical values,
            this loop will exit early on.
        for offset in range(1, len(ls)):
            v_a = ls[(i_a + offset) % len(ls)]
            v_b = ls[(i_b + offset) % len(ls)]
            if v_a < v_b:
                return True
            elif v_a > v_b:
                return False
        return False

    v_min = ls[0]
    i_best_first = 0
    i_best_last = 0
    i_best_total = 1
    for i in range(1, len(ls)):
        v = ls[i]
        if v_min > v:
            v_min = v
            i_best_first = i
            i_best_last = i
            i_best_total = 1
        elif v_min == v:
            i_best_last = i
            i_best_total += 1

    # all values match
    if i_best_total == len(ls):
        return 0

    # exit early if we're not matching another lists minimum
    if v_min_other is not None:
        if v_min != v_min_other:
            return -1
    # simple case, only one minimum
    if i_best_first == i_best_last:
        return i_best_first

    # otherwise find the minimum with the lowest values compared to all others.
    # start looking after the first we've found
    i_best = i_best_first
    for i in range(i_best_first + 1, i_best_last + 1):
        if (ls[i] == v_min) and (ls[i - 1] != v_min):
            if compare_rotations(i, i_best):
                i_best = i

    return i_best

def compare_circular_lists(ls_a, ls_b):
    # sanity checks
    if len(ls_a) != len(ls_b):
        return False
    if len(ls_a) <= 1:
        return (ls_a == ls_b)

    index_a = normalize_rotation_index(ls_a)
    index_b = normalize_rotation_index(ls_b, ls_a[index_a])

    if index_b == -1:
        return False

    if index_a == index_b:
        return (ls_a == ls_b)

    # cancel out 'index_a'
    index_b = (index_b - index_a)
    if index_b < 0:
        index_b += len(ls_a)
    index_a = 0  # ignore it

    # compare rotated lists
    for i in range(len(ls_a)):
        if ls_a[i] != ls_b[(index_b + i) % len(ls_b)]:
            return False
    return True

assert(compare_circular_lists([0, 9, -1, 2, -1], [-1, 2, -1, 0, 9]) == True)
assert(compare_circular_lists([2, 9, -1, 0, -1], [-1, 2, -1, 0, 9]) == False)
assert(compare_circular_lists(["Hello" "Circular", "World"], ["World", "Hello" "Circular"]) == True)
assert(compare_circular_lists(["Hello" "Circular", "World"], ["Circular", "Hello" "World"]) == False)

See: this snippet for some more tests/examples.


You can check to see if a list A is equal to a cyclic shift of list B in expected O(N) time pretty easily.

I would use a polynomial hash function to compute the hash of list A, and every cyclic shift of list B. Where a shift of list B has the same hash as list A, I'd compare the actual elements to see if they are equal.

The reason this is fast is that with polynomial hash functions (which are extremely common!), you can calculate the hash of each cyclic shift from the previous one in constant time, so you can calculate hashes for all of the cyclic shifts in O(N) time.

It works like this:

Let's say B has N elements, then the the hash of B using prime P is:

for (i=0; i<N ; i++)
    Hb = Hb*P + B[i];

This is an optimized way to evaluate a polynomial in P, and is equivalent to:

for (i=0; i<N ; i++)
    Hb += B[i] * P^(N-1-i);  //^ is exponentiation, not XOR

Notice how every B[i] is multiplied by P^(N-1-i). If we shift B to the left by 1, then every every B[i] will be multiplied by an extra P, except the first one. Since multiplication distributes over addition, we can multiply all the components at once just by multiplying the whole hash, and then fix up the factor for the first element.

The hash of the left shift of B is just

Hb1 = Hb*P + B[0]*(1-(P^N))

The second left shift:

Hb2 = Hb1*P + B[1]*(1-(P^N))

and so on...

NOTE: all math above is performed modulo some machine word size, and you only have to calculate P^N once.


To glue to the most pythonic way to do it, use sets !

from sets import Set
a = Set ([1, 1, 1, 0, 0])
b = Set ([0, 1, 1, 1, 0]) 
c = Set ([1, 0, 0, 1, 1])
  • this would also match strings with the same number of 0's and 1's not necessarily in the same order Nov 19, 2014 at 19:38
  • GeneralBecos : Just select those strings and check the order in a second step
    – Louis
    Nov 20, 2014 at 8:45
  • They aren't in the same linear order. They are in the same 'circular' order. What you describe as step 2 is the original problem. Nov 20, 2014 at 17:02

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