# arithmetic right shift shifts in 0s when MSB is 1

As an exercise I have to write the following function:
multiply x by 2, saturating to Tmin / Tmax if overflow, using only bit-wise and bit-shift operations.
Now this is my code:

``````// xor MSB and 2nd MSB. if diferent, we have an overflow and SHOULD get 0xFFFFFFFF. otherwise we get 0.
int overflowmask = ((x & 0x80000000) ^ ((x & 0x40000000)<<1)) >>31;
// ^ this arithmetic bit shift seems to be wrong
// this gets you Tmin if x < 0 or Tmax if x >= 0
int overflowreplace = ((x>>31)^0x7FFFFFFF);

// if overflow, return x*2, otherwise overflowreplace
``````

now when `overflowmask` should be `0xFFFFFFFF`, it is 1 instead, which means that the arithmetic bit shift `>>31` shifted in 0s instead of 1s (MSB got XORed to 1, then shifted to the bottom).
x is signed and the MSB is 1, so according to C99 an arithmetic right shift should fill in 1s. What am I missing?

EDIT: I just guessed that this code isn't correct. To detect an overflow it suffices for the 2nd MSB to be 1.
However, I still wonder why the bit shift filled in 0s.

EDIT:
Example: x = 0xA0000000

``````x & 0x80000000 = 0x80000000
x & 0x40000000 = 0
XOR => 0x80000000
>>31 => 0x00000001
``````

EDIT:
Solution:

``````int msb = x & 0x80000000;
int msb2 = (x & 0x40000000) <<1;
int overflowmask = (msb2 | (msb^msb2)) >>31;
int overflowreplace = (x >>31) ^ 0x7FFFFFFF;
``````
• Bitwise operations using signed values are always going to be a problem. – Some programmer dude Jan 9 at 11:17
• so I just need to come up with a different solution because c doesn't work as it states? – Duke Jan 9 at 11:18
• Can you please tell us some value of `x` where it doesn't work as you expect? And have you tried to divide the complex expressions you have into smaller and more easily debugable expressions to see that each small sub-expression gives the value you expect? – Some programmer dude Jan 9 at 11:29
• What's happening is that the `0x80000000` in `x & 0x80000000` becomes an unsigned integer, making the whole expression unsigned. Or `0x80000000` is a `long` or `long long` value, which means it's not negative. So you're shifting an unsigned or otherwise non-negative number, which means it's filled up with zeros instead of ones. I'm trying to find a reference or quote about this behavior for an answer. – Some programmer dude Jan 9 at 11:52
• It's either an `unsigned int` or a 64-bit signed integer (`long` or `long long`, depending on platform and compiler). – Some programmer dude Jan 9 at 11:58

`0x80000000` is treated as an unsigned number which causes everything to be converted to unsigned, You can do this:

``````// xor MSB and 2nd MSB. if diferent, we have an overflow and SHOULD get 0xFFFFFFFF. otherwise we get 0.
int overflowmask = ((x & (0x40000000 << 1)) ^ ((x & 0x40000000)<<1)) >>31;

// this gets you Tmin if x < 0 or Tmax if x >= 0
int overflowreplace = ((x>>31)^0x7FFFFFFF);

// if overflow, return x*2, otherwise overflowreplace
``````

OR write the constants in negative decimals

OR I would store all the constants in const int variables to have them guaranteed signed.

Even on twos-complement machines, the behaviour of right-shift (`>>`) on negative operands is implementation-defined.

A safer approach is to work with unsigned types and explicitly OR-in the MSB.

While you're at it, you probably also want to use fixed-width types (e.g. `uint32_t`) rather than failing on platforms that don't meet your expectations.

Never use bit-wise operands on signed types. In case of right shift on signed integers, it is up to the compiler if you get an arithmetic or a logical shift.

That's only one of your problems though. When you use a hex integer constant `0x80000000`, it is actually of type `unsigned int` as explained here. This accidentally turns your whole expression `(x & 0x80000000) ^ ...` into unsigned type because of the integer promotion rule known as "the usual arithmetic conversions". Whereas the `0x40000000` expression is signed int and works as (the specific compiler) expected.

Solution:

• All variables involved must be of type `uint32_t`.
• All hex constants involved must be `u` suffixed.
• To get something arithmetic shift portably, you would have to do
`(x >> n) | (0xFFFFFFFFu << (32-n))` or some similar hack.
• Hex literals are unsigned only if too big for `int`. Whilst it appears that the question assumes `int` is a 32-bit 2s-complement type, we answerers ought to be a bit more circumspect about making such assumptions! – Toby Speight Jan 9 at 14:01
• @TobySpeight It doesn't really matter because even if int is 16 bit, the hex literals would end up long/unsigned long respectively after the very same rules. – Lundin Jan 9 at 14:26
• It does matter, if `int` is 33 bits or more. – Toby Speight Jan 9 at 15:02
• @TobySpeight It is not, so you don't need to worry. If my code breaks on a highly fictional system that uses > 32 bit ints, I'm happy. The solution is not to fix the code, but to not use that compiler in the first place. You can also add `_Static_assert(sizeof(int) < 5, "Stop using crap.");`. – Lundin Jan 9 at 15:06
• Ah, there's the difference. When my code breaks, it makes me unhappy. – Toby Speight Jan 9 at 15:09