Though @jlahd answer is correct I will try and provide a brief explanation of the difference between a logical shift right and an arithmetic shift right (another nice diagram of the difference can be found here).

Please read the links first and then if you're still confused read below:

**Brief explanation of the two different shifts right**

Now, if you declare your variable as `int x = 8;`

the C compiler knows that this number is **signed** and when you use a shift operator like this:

```
int x = 8;
int y = -8;
int shifted_x, shifted_y;
shifted_x = x >> 2; // After this operation shifted_x == 2
shifted_y = y >> 2; // After this operation shifted_y == -2
```

The reason for this is that a *shift right* represents a *division by a power of 2*.

Now, I'm lazy so lets make `int`

's on my hypothetical machine 8 bits so I can save myself some writing. In binary 8 and -8 would look like this:

```
8 = 00001000
-8 = 11111000 ( invert and add 1 for complement 2 representation )
```

But in computing the binary number `11111000`

is 248 in decimal. It can only represent -8 if we remember that that variable has a sign...

If we want to keep the nice property of a shift where the shift represents a division by a power of 2 (this is really useful) and we want to now have signed numbers, we need to make two different types of right shifts because

```
248 >> 1 = 124 = 01111100
-8 >> 1 = -4 = 11111100
// And for comparison
8 >> 1 = 4 = 00000100
```

We can see that the first shift inserted a 0 at the front while the second shift inserted a 1. This is because of the difference between the signed numbers and unsigned numbers, in two's complement representation, when dividing by a power of 2.

To keep this nicety we have two different right shift operators for signed and unsigned variables. In assembly you can explicitly state which you wish to use while in C the compiler decides for you based on the declared type.

**Code generalisation**

I would write the code a little differently in an attempt to keep myself at least a little platform agnostic.

```
#define ROTR(x,n) (((x) >> n) | ((x) << ((sizeof(x) * 8) - n)))
#define ROTR(x,n) (((x) >> n) | ((x) << ((sizeof(x) * 8) - n)))
```

This is a little better but you still have to remember to keep the variables unsigned when using this macro. I could try casting the macro like this:

```
#define ROTR(x,n) (((size_t)(x) >> n) | ((x) << ((sizeof(x) * 8) - n)))
#define ROTR(x,n) (((size_t)(x) >> n) | ((x) << ((sizeof(x) * 8) - n)))
```

but now I'm assuming that you're never going to try and rotate an integer larger than `size_t`

...

So I would do the following, although it may not be as pretty as the first it should work better than casting...

```
#define ROTR(x,n) ((((x) >> n) & (~(0u) >> n)) | ((x) << ((sizeof(x) * 8) - n)))
#define ROTR(x,n) ((((x) >> n) & (~(0u) >> n)) | ((x) << ((sizeof(x) * 8) - n)))
```

Cavats: This is a slightly more complicated expansion for genericity sake and the compiler may no longer be able to figure out that you are infact trying to do a rotation (and use the right assembly instruction to make it faster).

So in the end @jlahd's solution will work better, whilst my one might help you make things more generic (at a cost).

`>>`

is implementation defined for negative`signed int`

- i.e. you can't assume whether it's an arithmetic or logical shift unless you can guarantee the code's never going to see a different compiler or platform. – Notlikethat Feb 20 at 1:41`int`

is 32 bits, a left or right shift of 32 is not defined. 3) For portability, an`int`

bit size is`sizeof(int)*CHAR_BIT`

. – chux Feb 20 at 2:32