Given two integers a and b, how can we check that b is a rotated version of a?

For example if I have a = 0x01020304 (in binary 0000 0001 0000 0010 0000 0011 0000 0100), then the following b values are correct:

  • ...
  • 0x4080C1 (right-rotated by 2)
  • 0x810182 (right-rotated by 1)
  • 0x2040608 (left-rotated by 1)
  • 0x4080C10 (left-rotated by 2)
  • ...
  • 3
    I wonder if there is any solution, other than actually rotating the original value and check for a match. :/ – Peter Jaloveczki Jun 7 '13 at 8:43
  • Just 32 times loop (32 bit in your case) and check for a match. – Boris Jun 7 '13 at 8:45
  • 2
    I have no idea how much this would help speed things up, but you could try and use the POPCNT compiler intrinsic to count the number of bits of a and b, respectively. If the numbers differ, the answer must be false. Otherwise you do the full check for all possible rotations. – jogojapan Jun 7 '13 at 9:01
  • This is hard because rotation is not a mathematical operation, unlike shift (which is a multiply or divide by power of two) – MSalters Jun 7 '13 at 10:54
  • I'm still waiting for someone to post an answer based on polynomial division :) – avakar Jun 7 '13 at 13:06

In C++, without string conversion and assuming 32 bits int:

void test(unsigned a, unsigned b)
  unsigned long long aa = a | ((unsigned long long)a<<32);
    if (unsigned(aa) == b) return true;
return false;
  • 1
    It seems this one is the best answer. A little update to include b in the parameter. Thanks – user2462322 Jun 8 '13 at 0:59
  • Just some small notes: (1) It should rather be unsigned long long, shouldn't it? (2) The type of a shift expression is that of the left operand, so you should rather cast the a in there to unsigned long long, just using 32LL is not enough. – Chris says Reinstate Monica Jun 8 '13 at 14:10
  • You can eventually test if(unsigned(aa)==a) return false; because of symetry, some numbers have less than 32 different rotations, like 0xAAAAAAAA, though I don't know if it will statistically fast up or slow down – aka.nice Jun 9 '13 at 23:06
  • 1
    Or just do {...} while( unsigned(aa)!=a); it will iterate 32 times at most, sometimes less. – aka.nice Jun 9 '13 at 23:23

For n bit numbers you can use KMP algorithm to search b inside two copies of a with complexity O(n).


i think you have to do it in a loop (c++):

// rotate function
inline int rot(int x, int rot) {
   return (x >> rot) | (x << sizeof(int)*8 - rot));

int a = 0x01020304;
int b = 0x4080C1;
bool result = false;

for( int i=0; i < sizeof(int)*8 && !result; i++) if(a == rot(b,i)) result = true;
  • Doesn't work for the same a and b. You should start loop from i=0. – Boris Jun 7 '13 at 8:58
  • 3
    Fist of all I'd rather use unsigned ints for any reasonable bit manipulation, then CHAR_BIT would be a bit better fit than 8 (or just std::numeric_limits<unsigned int>::digits instead of the whole sizeof madness), but Ok, those are just minor flaws. In general this is probably the best approach still. – Chris says Reinstate Monica Jun 7 '13 at 9:14

In the general case (assuming arbitrary-length integers), the naive solution of consisting each rotation is O(n^2).

But what you're effectively doing is a correlation. And you can do a correlation in O(n log n) time by going via the frequency domain using an FFT.

This won't help much for length-32 integers though.

  • That sounds interesting. Could you be more specific?? – Sungmin Jun 7 '13 at 10:39
  • It's wrong, though: considering each rotation is only O(N). You rotate a to match b, but b itself isn't rotated. – MSalters Jun 7 '13 at 11:00
  • @MSalters: There are O(N) rotations and comparisons, but each comparison is also O(N). – Oliver Charlesworth Jun 7 '13 at 11:11
  • 3
    I think this is one of the cases where talking about complexity is useless. If the question was about BigIntegers I would side with you. However in this case the CPU doesn't compare bit by bit so the O(N^2) seems a bit misleading to me. – Honza Brabec Jun 7 '13 at 14:45
  • @HonzaBrabec: I see what you mean, but the reason I posted this general response is because the OP specifically said "integers" rather than "ints"; I may have been reading too much into that though... – Oliver Charlesworth Jun 7 '13 at 14:49

By deriving the answers here, the following method (written in C#, but shall be similar in Java) shall do the checking:

public static int checkBitRotation(int a, int b) {
    string strA = Convert.ToString(a, 2).PadLeft(32, '0');
    string strB = Convert.ToString(b, 2).PadLeft(32, '0');
    return (strA + strA).IndexOf(strB);

If the return value is -1, b is not rotated version of a. Otherwise, b is rotated version of a.

  • 5
    Meh, before converting the whole thing into strings and doing a string search, I'd rather execute that simple integer bit shift loop 32 times. – Chris says Reinstate Monica Jun 7 '13 at 9:10
  • 2
    +1 for a neat trick I wouldn't have thought of. Probably slower than just brute forcing it, but still neat. – Retired Ninja Jun 7 '13 at 9:18
  • you can use std::bitset<32>::to_string(), not much to it. – TemplateRex Jun 7 '13 at 9:54

I would use Integer.rotateLeft or rotateRight func

static boolean isRotation(int a, int b) {
    for(int i = 0; i < 32; i++) {
        if (Integer.rotateLeft(a, i) == b) {
            return true;
    return false;
  • 1
    You're only doing 30 tests out of the 32 possible values. While it's arguable whether x == y means no rotation, you're still missing at least one case. – syam Jun 7 '13 at 8:53
  • well, on the other hand then b is not a rotated version of a – Evgeniy Dorofeev Jun 7 '13 at 8:55
  • Which is why I said it was arguable. But you still miss the 31th rotation, even if you consider the 0th (aka. 32th) rotation should return false. – syam Jun 7 '13 at 9:10
  • I agree, that's a bug, fixed – Evgeniy Dorofeev Jun 7 '13 at 9:14
  • input is a and b, but you check x and y? – David Jun 7 '13 at 9:23

If a or b is a constant (or loop-constant), you can precompute all rotations and sort them, and then do a binary search with the one that isn't a constant as key. That's fewer steps, but the steps are slower in practice (binary search is commonly implemented with a badly-predicted branch), so it might not be better.

In the case that it's really a constant, not a loop-constant, there are some more tricks:

  • if a is 0 or -1, it's trivial
  • if a has only 1 bit set, you can do the test like b != 0 && (b & (b - 1)) == 0
  • if a has 2 bits set, you can do the test like ror(b, tzcnt(b)) == ror(a, tzcnt(a))
  • if a has only one contiguous group of set bits, you can use

    int x = ror(b, tzcnt(b));
    int y = ror(x, tzcnt(~x));
    const int a1 = ror(a, tzcnt(a));     // probably won't compile
    const int a2 = ror(a1, tzcnt(~a1));  // but you get the idea
    return y == a2;
  • if many rotations of a are the same, you may be able to use that to skip certain rotations instead of testing them all, for example if a == 0xAAAAAAAA, the test can be b == a || (b << 1) == a
  • you can compare to the smallest and biggest rotations of the constant for a quick pre-test, in addition to the popcnt test.

Of course, as I said in the beginning, none of this applies when a and b are both variables.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy