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.

number of bitsof`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