Without using any external counters or other state, I'm looking for an *efficient* function which takes an n-bit value (32 bits or thereabouts) and returns the subsequent value in a Gray code.

That is:

```
int fn(int x)
{
int y = gray_to_binary(x);
y = y + 1;
return binary_to_gray(y);
}
```

But while the `binary_to_gray()`

function is trivial (`x ^ (x >> 1)`

), the corresponding `gray_to_binary()`

is not so trivial at all (a loop of `log(n)`

iterations).

Perhaps there is a more efficient sequence of operations? Either for the standard reflected Gray code, or for another Gray code chosen to suit this problem.

**Aside:** I see two possible solution types to this problem -- one is to choose a code that is easier to convert to binary and to use the form given above (or to demonstrate a more efficient conversion to binary for reflected codes), and the other is to defer conversion to binary altogether and to produce a method which walks through a gray code without the use of a binary increment.

In the latter case, it might turn out to be especially difficult to convert the resulting code to binary. That's likely a down-side in practical terms, but it'd still be an interesting thing to see.

**Update:** Since it's been pointed out that the Gray decode is only `log(n)`

operations (using either of two different techniques), I spent some time trying to figure out if that is a strict limit on how far things can be simplified. All bits must be considered when determining the next operation to perform, otherwise the 'considered' bits would fail to change and the function would oscillate between two values. The input must be compressed, in some way, to a manageable scale to determine the next operation to perform.

To make it `log(n-k)`

operations, a 2^{k}-entry LUT could be used to short-cut the last `k`

operations (a comment suggests `k=32`

).

Another technique which came to mind which can often reduce things very quickly is a combination of multiplication and bitmasks. For example, to compute the parity in order to implement the parity-based algorithm.

From the multiply-and-bitmask approach, it seems like there might be space to invent a Gray code which simplifies the set of operations even further... but I don't imagine any such code is known.

`log(n)`

steps, not`n`

. Like`x ^= x >> 1; x ^= x >> 2; x ^= x >> 4; x ^= x >> 8;`

etc. – harold Jul 5 '13 at 13:58`int[2^32] gray2binary`

where you use the grayCode as index and get the binary code as value of the arrayEntry.;-)– MrSmith42 Jul 5 '13 at 14:53