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I am attempting to determine if I can compute the sum of two 32 bit integers without overflow, while making use of only certain bitwise and other operators. So, if the integers x and y can be added without overflow, the following code should return 1, and 0 otherwise.

(((((x >> 31) + (y >> 31)) & 2) >> 1))

However, it returns 0 when it should be 1 and vice versa. When I employ the logical NOT (!) operator, or bitwise XOR (^) with 0x1, it does not fix the issue.

!(((((x >> 31) + (y >> 31)) & 2) >> 1))

(((((x >> 31) + (y >> 31)) & 2) >> 1) ^ 0x1)

^ these don't work.

Thanks in advance.

share|improve this question
Yuck​​​​​​​​​​. – GManNickG Sep 13 '10 at 0:54
My advice is to cheat: first cast to unsigned, so there's never an overflow. Then again, you pretty much need to anyway, since you don't know what you'll get from right shifting a negative number. – Jerry Coffin Sep 13 '10 at 0:59
@Jerry Coffin: even with unsigned there can still be overflow while adding two large negative numbers. – kriss Sep 13 '10 at 2:20
Hmm...a negative unsigned number. Just the concept already seems to cause an overflow... – Jerry Coffin Sep 13 '10 at 3:37
Just FYI, on most processors, it's far more efficient to just go ahead and add two integers, then check to see if overflow occurred than it is to determine if a computation is going to overflow before you perform it. – Stephen Canon Sep 13 '10 at 5:32
up vote 8 down vote accepted

This is a bit cleaner:

~(x & y) >> 31


kriss' comment is correct. all this code does is check that the two MSBs are both set.

I was just looking at kriss' answer, and it occurred to me that the same thing can be done using only a single addition, plus bitwise operators, assuming unsigned ints.

((x & 0x7FFFFFFF) + (y & 0x7FFFFFFF)) & 0x80000000 & (x | y)

The first parenthesised section sets both MSB to 0 then adds the result. Any carry will end up in the MSB of the result. The next bitmask isolates that carry. The final term checks for a set MSB on either x or y, which result in a carry overall. To meet the spec in the question, just do:

~(((x & 0x7FFFFFFF) + (y & 0x7FFFFFFF)) & 0x80000000 & (x | y)) >> 31
share|improve this answer
Well, it's shorter and cleaner than the OP's code, but has the same flaw. It does not check for possible overflow at all, just that both numbers are large unsigned integers. What about 0xF0000000+0x7F000000 ? Looks like unnoticed overflow. – kriss Sep 13 '10 at 2:27
True. I was just trying to replicate the effect of Rowhawn's code. I didn't even think about what it was doing. Thinking about it now I'm not sure it's feasible to do what he wants. Take the extreme example of 0xFFFFFFFF+0x1. That will overflow but it's hard to check using bitwise operators. The simplest thing may be to just do the addition and check for overflow. – Andrew Cooper Sep 13 '10 at 2:59

Let's suppose both numbers are unsigned integers. If you work with signed integers, it would be a little be more tricky as there is two ways to get overflow, either adding two large positives of adding two large negative. Anyway checking the most significant bits won't be enough, as addition propagates carry bit, you must take it into account.

For unsigned integers, if you don't care to cheat an easy way is:

 (x+y < x) || (x+y < y)

This will work as most compilers won't do anything when overflow happen, just let it be.

You can also remarks that for overflow to happen at least one of the two numbers must have it's most significant bit set at 1. Hence something like that should work (beware, untested), but it's way more compilcated than the other version.

/* both Most Significant bits are 1 */
/* x MSb is 1 and carry propagate */
/* y MSb is 1 and carry propagate */
share|improve this answer
Your first code is guaranteed to work, as unsigned numbers operate under modulo. – GManNickG Sep 13 '10 at 2:47
@GMan: nice to know. Is it in standard ? Still thought some rare CPU raised hardware exceptions when overflow occurred and that it was allowed by standard. But I may be wrong. – kriss Sep 13 '10 at 2:51
This code can be simplified to a single addition + bitwise ops. See my updated answer. – Andrew Cooper Sep 13 '10 at 3:22
GMan is correct; kriss is mistaken. Hardware exceptions are only allowed for signed integer overflow. Unsigned arithmetic never overflows; it wraps modulo UINT_MAX+1 (or whatever the right value for the type is) according to the specification, and always has done so. – R.. Sep 13 '10 at 4:27
@kriss: Yes, a compiler must not do anything special when an unsigned integral value overflows. Just needs to wrap. – GManNickG Sep 13 '10 at 16:48

The logical ! is working fine for me.

me@desktop:~$ cat > so.c
#include <stdio.h>

void main() {
    int y = 5;
    int x = 3;
    int t;
    t = (((((x >> 31) + (y >> 31)) & 2) >> 1));
    printf("%d\n", t);
    t = !(((((x >> 31) + (y >> 31)) & 2) >> 1));
    printf("%d\n", t);
me@desktop:~$ gcc -o so so.c
me@desktop:~$ ./so
me@desktop:~$ uname -a
Linux desktop 2.6.32-23-generic #37-Ubuntu SMP Fri Jun 11 07:54:58 UTC 2010 i686 GNU/Linux
share|improve this answer

There is no simple bit-arithmetic-based test for overflow because addition involves carry. But there are simple tests for overflow that do not involve invoking overflow or unsigned integer wrapping, and they're even simpler than doing the addition then checking for overflow (which is of course undefined behavior for signed integers):

For unsigned integers x and y: (x<=UINT_MAX-y)

For signed integers, first check if they have opposite signs. If so, addition is automatically safe. If they're both positive, use (x<=INT_MAX-y). If they're both negative, use (x>=INT_MIN-y).

share|improve this answer
The unsigned case can be improved by just checking the result: (x + y >= x) or (x + y >= y) to check for a valid result, whatever is more convenient. In the signed case, there is no need to check for opposite signs. Just use (y >= 0 ? x <= INT_MAX - y : x >= INT_MIN - y). – gnasher729 May 18 '14 at 9:34
@gnasher729: Yes, at a glance that seems to work. – R.. May 18 '14 at 13:00

Are those signed integers by any chance? Your logic looks like it should be fine for unsigned integers (unsigned int) but not for regular ints, since in that case the shift will preserve the sign bit.

share|improve this answer
yes, they are signed integers, sorry i forgot to specify – Rowhawn Sep 13 '10 at 21:02

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