I was reading the C Standard the other day, and noticed that unlike signed integer overflow (which is undefined), unsigned integer overflow is well defined. I've seen it used in a lot of code for maximums, etc. but given the voodoos about overflow, is this considered good programming practice? Is it in anyway insecure? I know that a lot of modern languages like Python do not support it- instead they continue to extend the size of large numbers.

12 Answers 12


Unsigned integer overflow (in the shape of wrap-around) is routinely taken advantage of in hashing functions, and has been since the year dot.

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    year dot: Is that 1970? – Martin York Jun 12 '09 at 19:45
  • As the origins of computing are in cryptography, I suspect it is sometime in the 1940s. – anon Jun 12 '09 at 19:51
  • Though I don't actually get why insist on signed integer overflow. Using an unsigned integer is just as good and can be worked around to detect overflow. – Eduard - Gabriel Munteanu Jun 12 '09 at 19:54
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    @Martin: On UNIX. But MS has been doing it in Excel since 1900 on Windows, and 1904 on Mac. – Steve Jessop Jun 12 '09 at 19:54
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    @eduard We are talking about UNSIGNED OVERFLOW. No one is insisting on using signed overflow - quite the reverse! – anon Jun 12 '09 at 19:58

One way where I could think of unsigned integer overflow causing a problem is when subtracting from a small unsigned value, resulting in it wrapping to a large positive value.

Practical advice for integer overflows:

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    I'm asking about unsigned overflow – user122147 Jun 12 '09 at 19:33
  • This is unsigned. Using unsigned arithmetic, subtract 200 from 100. You'll get a large value (how large depends on the range of values). Unsigned arithmetic in C is defined as modular, or you could say wrap-around. – David Thornley Jun 12 '09 at 19:56
  • @DavidThornley: I think the question was whether it's good practice to rely upon such behavior. My personal thought is that it's fine to rely upon such behavior if and only if one uses rigid typecasts every time one wishes to enforce it. If a and b are e.g. UInt32, the expression (UInt32)(a-b) will yield wrapping behavior, and it will be clear that such behavior is expected. The expectation that (a-b) is supposed to yield wrapping behavior, however, is far less obvious, and on machines where int is bigger than 32 bits, it might in fact not yield such behavior. – supercat Aug 10 '12 at 15:17

To put it shortly:

It is perfectly legal/OK/safe to use unsigned integer overflow as you see fit as long as you pay attention and adhere to the definition (for whatever purpose - optimization, super clever algorithms, etc.)


Just because you know the minutiae of the standard doesn't mean the person maintaining your code does. That person may have to waste time worrying about this while debugging later, or have to go look up the standard to verify this behavior later.

Sure, we expect proficiency with the reasonable features of a language in a working programmer -- and different companies / groups have a different expectation about where that reasonable proficiency is. But for most groups this seems to be a bit much to expect the next person to know off the top of his/her head and not have to think about it.

If that weren't enough, you're more likely to run into compiler bugs when you're working around the edges of the standard. Or worse, the person porting this code to a new platform may run into them.

In short, I vote don't do it!


I use it all the time to tell if it is time to do something.

UInt32 now = GetCurrentTime()

if( now - then > 100 )
   // do something

As long as you check the value before 'now' laps 'then', you are fine for all values of 'now' and 'then'.

EDIT: I guess this is really an underflow.

  • I believe the above code will fail on systems where an int is 64 bits, since the operands to the subtraction would be extended to signed 64-bit integers, so if 'now' is 0 and then is 4294967295u (0xFFFFFFFF) the result of the subtraction would not be 1 but -4294967295. Casting the result of the subtraction to a UInt32 before the comparison would avoid that problem since (UInt32)(-4294967295) would be 1. – supercat Aug 10 '12 at 15:13

I wouldn't rely on it just for readability reasons. You're going to be debugging your code for hours before you figure out where you're resetting that variable to 0.

  • Not really, as long as the behavior is documented and commented upon. Besides, there are legitimate reasons for (un)signed integer overflow, for example in fixed-width timestamps, where precision is more important and overflow can be reasonably detected. – Eduard - Gabriel Munteanu Jun 12 '09 at 19:46

Another place where unsigned overflow can be usefully used is when you have to iterate backwards from a given unsigned type:

void DownFrom( unsigned n )
    unsigned m;

    for( m = n; m != (unsigned)-1; --m )
        DoSomething( m );

Other alternatives are not as neat. Trying to do m >= 0 doesn't work unless you change m to signed, but then you might be truncating the value of n - or worse - converting it to a negative number on initialisation.

Otherwise you have to do !=0 or >0 and then manually do the 0 case after the loop.

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    for(m = n; m < n; --m) – Niki Yoshiuchi Jun 12 '09 at 19:59
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    Or "do {DoSomething(n);} while (n-- != 0);". With "if (n != (unsigned)-1)" at the start, if it's actually desirable that -1 is a magic input value meaning "do nothing", as it is in the above code. – Steve Jessop Jun 12 '09 at 20:07
  • @Niki: doesn't work, your loop does nothing since m < n fails on the first time of asking. – Steve Jessop Jun 12 '09 at 20:09
  • Yes, often (unsigned)-1 - i.e. the largest possible unsigned is a special value but it doesn't have to be. – CB Bailey Jun 12 '09 at 20:16
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    For code readability, wouldn't it be better to use UINT_MAX than (unsigned)-1? Also, methinks this might be the right place for a do... while loop; m=n; do { DoSomething(m); } while(m-- >0); will execute the 0 case – Benubird Nov 25 '10 at 17:01

Since signed numbers on CPUs can be represented in different ways, 99.999% of all current CPUs use twos-complement notation. Since this is the majority of machines out there, it is difficult to find a different behaviour although the compiler might check it (fat chance). The C specs however must account for 100% of the compilers so have not defined its behaviour.

So it would make things more confusion, which is a good reason to avoid it. However, if you have a really good reason (say, performance boost of factor of 3 for critical part of code), then document it well and use it.

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    You are referring to signed integers. The C standard documents the behavior of unsigned integers, and that's what the question is about. – David Thornley Jun 12 '09 at 19:53

It's fine to rely on overflow as long as you know WHEN it will occur ...

I, for example, had troubles with C implementation of MD5 when migrating to a more recent compiler... The code did expect overflow but it also expected 32 bits ints.

With 64 bits the results were wrong !

Fortunately that's what automated tests are for : I caught the problem early but this could have been a real horror story if gone unnoticed.

You could argue "but this happens rarely" : yes but that's what makes it even more dangerous ! When there is a bug, everybody is suspicious of code written in the last few days. No one is suspicious f code that "just worked for years" and usually no one still knows how it works...

  • This is a case where a compile-time assertion to check the assumption that sizeof(int)==4 was valid would be a good thing. That would have thrown an error even before the tests were run. – RBerteig Jun 12 '09 at 21:53

If you use it wisely (well commented and readable), you can benefit from it by having smaller and faster code.


siukurnin makes a good point, that you need to know when overflows will occur. The easiest way to avoid the portability issue he described is to use the fixed-width integer types from stdint.h. uint32_t is an unsigned 32-bit integer on all platforms and OSes, and won't behave differently when compiled for a different system.


I would suggest always having an explicit cast any time one is going to rely upon unsigned numbers wrapping. Otherwise there may be surprises. For example, if "int" is 64 bits, code like:

UInt32 foo,bar;
if ((foo-bar) < 100) // Report if foo is between bar and bar+99, inclusive)
  ... do something

may fail, since "foo" and "bar" would get promoted to 64-bit signed integers. Adding a typecast back to UInt32 before checking the result against 100 would prevent problems in that case.

Incidentally, I believe the only portable way to directly get the bottom 32 bits of the product of two UInt32's is to cast one of the ints to a UInt64 prior to doing the multiply. Otherwise the UInt32's might be converted to signed Int64's, with the multiplication overflowing and yielding undefined results.

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