9

EDIT Public health warning - this question includes a false assumption about undefined behaviour. See accepted answer.

After a reading recent blog post, I've been thinking a lot about the practicality of avoiding all standards-undefined assumptions in C and C++ code. Here is a snippet cut out of C++, to do an unsigned 128-bit addition...

void c_UInt64_Pair::operator+= (const c_UInt64_Pair &p)
{
  m_Low  += p.m_Low;
  m_High += p.m_High;

  if (m_Low < p.m_Low)  m_High++;
}

This clearly relies on assumptions about overflow behaviour. Obviously most machines can support a binary integer of the right kind (though perhaps building from 32-bit chunks or whatever), but there's apparently a growing chance that the optimiser may exploit the standards-undefined behaviour here. That is, the only way that the m_Low < p.m_Low condition can pass is if m_Low += p.m_Low overflows, which is undefined behaviour, so the optimiser can legally decide that the condition always fails. In which case, this code is simply broken.

The question is, therefore...

How can you write a reasonably efficient version of the above without relying on undefined behaviour?

Assume that you have an appropriate 64-bit binary machine integer, but that you have a malicious compiler that will always interpret your undefined behaviour in the worst possible (or impossible) way. Also, assume that you don't have some special built-in, intrinsic, library or whatever to do it for you.

EDIT minor clarification - this isn't just about detecting overflow, but also ensuring that both m_Low and m_High end up with the correct modulo 2^64 results, which is also standards-undefined.

  • 3
    1/ This is not C. Why do you tag this question "C"? 2/ If this were C, and perhaps even in C++, this would not rely on undefined behavior: unsigned integral types overflows are defined and have modulo behavior: 6.2.5.9 in the C99 standard. – Pascal Cuoq Aug 25 '10 at 19:26
  • @Pascal: Actually, see section 5.4 of the most recent draft (I don't have the C++03 standard here, but I believe that behavior has not changed) -- "If during the evaluation of an expression, the result is not mathematically defined or not in the range of representable values for its type, the behavior is undefined." – Billy ONeal Aug 25 '10 at 19:28
  • 2
    @Pascal - (1) the question is equally about C and C++. Providing an example in just one doesn't mean the question is only about that one. (2) When did that happen? If it's true it's the answer (C++ may not have imported the relevant C rule yet, but if not, it no doubt will), so put it in an answer with a reference and I'll accept. – Steve314 Aug 25 '10 at 19:31
  • Okay, that was a bit of a knee-jerk reaction after seeing to many "C/C++" questions. For subtle questions such as these, they simply cannot be considered to be the same language. Please remember of my remark only the "in C99, this code would be defined" part. – Pascal Cuoq Aug 25 '10 at 19:35
  • @Steve314: And you know it's equally about both how? In this particular case, I believe it is. In other cases, it isn't. Suppose you were to ask about the type of 'a', for example: different answers in C and C++. – David Thornley Aug 25 '10 at 19:38
14

From the C++ 1998 standard, 3.9.1(4): "Unsigned integers, declared unsigned, shall obey the laws of arithmetic modulo 2^n where n is the number of bits in the value representation of that particular size of integer." Note that "integer", here, refers to any integer type rather than just int.

Therefore, assuming that those are unsigned integers, like the "UInt64" in the type suggests, this is defined behavior in C++ and should work as expected.

  • What is the C++ 1995 standard? I am aware of '99, '03... never heard of that one. In any case, while that is true, that does not mean that overflow behavior is defined, see the section I quoted above -- "If during the evaluation of an expression, the result is not mathematically defined or not in the range of representable values for its type, the behavior is undefined." – Billy ONeal Aug 25 '10 at 19:49
  • 4
    @Billy, since unsigned types follow rules of modulo arithmetic, there will never be a result that's outside the range of representable values, so the behavior is defined. The footnote on 3.9.1/4 says as much. – Rob Kennedy Aug 25 '10 at 19:59
  • 2
    @Billy ONeal: Let's assume that the cite is correct for C++. In any case the same modulo rule applies to C99. Arithmetic modulo 2^n is always well defined, there is no ambiguity about the results: they are always in the range 0 <= x < 2^n. So the extra clause about mathematically undefined behavior can never apply to unsigned types. Unsigned integer types wrap, but they don't overflow. – Jens Gustedt Aug 25 '10 at 20:04
  • 2
    You might also cite the C standard. – R.. Aug 26 '10 at 0:45
  • 1
    What would be the nicest portable way of getting the lower 32 bits of the product of two arbitrary 32-bit numbers whose product might exceed 2^63? If "unsigned int" is 32 bits or smaller, or if "signed int" is 65 bits or bigger, there'd be no problem, but what if both are 64 bits? The UInt32's convert to Int64's, and the product then yields undefined results. Casting an operand to a UInt64 might work, but that would likely add considerable extra code for processors where an 'int' would otherwise be 32 bits. – supercat Mar 21 '11 at 17:44
0

If you want an actually efficient method, you'll have to code in something other than C or C++. For reasonably efficient, you have to ensure that overflow never happens, and detect and compensate for when it would have.

Basically, for each 64-bit component, you need to separately calculate the additions using the low 63 bits, and the highest bits. From these separate calculations you can work out what the 64-bit total was, and if there was a carry.

Then when you do the upper 64-bit add, you add in the carry, if there is one. If a carry results from that, then you've overflowed your 128-bit variable, and you'll need to trigger an exception, or otherwise handle the case.

  • 4
    Nope; what you say is true for signed integral types, but not unsigned. – David Thornley Aug 25 '10 at 19:42
  • Aannd... why would you not be able to efficiently do this in C or C++? What alternative would you suggest would be more efficient? – Billy ONeal Aug 25 '10 at 19:57
  • 1
    Most efficient would be to actually use the hardware facilities provided for just this purpose, be that 128-bit registers or carry flags. – swestrup Aug 25 '10 at 20:34
  • But I do stand corrected on the whole signed/unsigned thing. For some reason I seemed to recall that all arithmetic overflows were undefined. – swestrup Aug 25 '10 at 20:35
  • @swestrup - I was fooled too :-( – Steve314 Aug 25 '10 at 21:42

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