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I believe that during arithmetic overflow (in the context of an integer variable being assigned a value too large for it to hold), bits beyond the end of the variable could be overwritten.

But in the following C++11 program does this really still hold? I don't know whether it's UB, or disallowed, or implementation-specific or what, but when I take the variable past its maximum value, on a modern architecture, will I actually see arithmetic overflow of bits in memory? Or is that really more of a historical thing?

int main() {
   // (not unsigned; unsigned is defined to wrap-around)
   int x = std::numeric_limits<int>::max();
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"the scary notion that bits beyond the end of the variable could be overwritten." Really - has that ever happened? To me, 'overflow' is a CPU flag that gets set by add etc. – Rup Dec 14 '11 at 10:52
Do you actually know of any architecture (obsolete or otherwise) where such an increment could potentially modify memory beyond that occupied by x? – NPE Dec 14 '11 at 10:56
also, overflow happens mainly in arrays and pointers, not in numbers. – CamelCamelCamel Dec 14 '11 at 10:59
This question mixes two unrelated concepts: numeric overflow and buffer overflow. Though they share am english term they are completely unrelated and handled/specified differently by the standard. – edA-qa mort-ora-y Dec 14 '11 at 11:45
It really is weird that such a high level question gets down voted at all while loads of relatively stupid simple newby questions get upvoted all over SO. +1 to balance that weirdness. – markus Dec 14 '11 at 15:35
up vote 7 down vote accepted

I don't know whether it's UB

It is undefined, as specified in C++11 5/4:

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.

(As you say, it is defined for unsigned types, since they are defined by 3.9.1/4 to obey modular arithmetic)

on a modern architecture, will I actually see arithmetic overflow of bits in memory?

On all the modern architectures I know of (x86, ARM, 68000, and various DSPs), arithmetic is modular, with fixed-width 2s-complement results; on those architectures that can write the result to memory rather than registers, it will never overwrite more memory than the result size. For addition and subtraction, there is no difference to the CPU between signed and unsigned arithmetic. Overflow (signed or unsigned) can be detected from the state of CPU flags after the operation.

I could imagine a compiler for, say, a 32-bit DSP that tried to implement arithmetic on 8 or 16-bit values packed into a larger word, where overflow would affect the rest of the word; however, all compilers I've seen for such architectures just defined char, short and int to be 32-bit types.

Or is that really more of a historical thing?

It would have happened on Babbage's Difference Engine, since "memory" is a single number; if you partition it into smaller numbers, and don't insert guard digits, then overflow from one will alter the value of the next. However, you couldn't run any non-trivial C++ program on this architecture.

Historically, I believe some processors would produce an exception on overflow - that would be why the behaviour is undefined.

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Alrighty. Thanks! Looks like I've been wrong about arithmetic overflows forever. – Lightness Races in Orbit Dec 14 '11 at 14:38

The content of addresses almost never really "overflowed". For example we would expect primitive integers to roll over their values. See http://www.pbm.com/~lindahl/mel.html.

I think overflow is when the pointers move beyond their desired limits so that you have pointers that point to unexpected places.

He had located the data he was working on near the top of memory -- the largest locations the instructions could address -- so, after the last datum was handled, incrementing the instruction address would make it overflow. The carry would add one to the operation code, changing it to the next one in the instruction set: a jump instruction. Sure enough, the next program instruction was in address location zero, and the program went happily on its way.

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Ah! Hmm... I see... – Lightness Races in Orbit Dec 14 '11 at 10:58

Personally, I have never seen an architecture where overflow would cause memory outside the variable to be overwritten.

I think you should read overflow as you leave a domain that is well defined (like the positive values of a signed integer) and enter one that is not well defined.

Concretely, lets take the max short value, 0x7FFF. If you add one to it you get 0x8000. This value has different meaning depending on if you use one-complement or two-complement negative numbers, both of which are allowed by the C standard.

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It still happens. With floating point arithemitic it is sometimes necessary to ensure that the caluculations are dcarried out in the right order to ensure that this event is unlikely to happen. (also it can reduce rounding errors!)

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This is not overflow in the sense that the memory outside a floating-point value is overwritten, which is what the question was about. – Lindydancer Dec 14 '11 at 11:00

There are two main overflows in Computer buisness

Arithmetic overflow: like in your example which is defined and needed for work

Negativ example:

int a = std::numeric_limits<int>::max()/2;
int b = a + a + 3; // b becomes negativ and the plane crashes

Positiv example:

double a = std::numeric_limits<double>::max()/2;
double b = a + a + 3; // b becomes Inf and it is determined

Thats how the overflow is defined for Processor integer and floatingpoint units and it will not go awayand has to be handled.

Memory Overflow: Still happens if things do not match like

  • memory size
  • calling conventions
  • data type size of client server
  • memory alignment
  • ...

A lot of security issues are based on memory overflow.

Read wikipedia for more facets of overflows: http://en.wikipedia.org/wiki/Overflow

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Please explain "defined and needed for work" – Lightness Races in Orbit Dec 14 '11 at 11:01

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