The new C++ standard still refuses to specify the binary representation of integer types. Is this because there are real-world implementations of C++ that don't use 2's complement arithmetic? I find that hard to believe. Is it because the committee feared that future advances in hardware would render the notion of 'bit' obsolete? Again hard to believe. Can anyone shed any light on this?

Background: I was surprised twice in one comment thread (Benjamin Lindley's answer to this question). First, from piotr's comment:

Right shift on signed type is undefined behaviour

Second, from James Kanze's comment:

when assigning to a long, if the value doesn't fit in a long, the results are implementation defined

I had to look these up in the standard before I believed them. The only reason for them is to accommodate non-2's-complement integer representations. WHY?

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    Why are you writing code that depends on signed values being stored as two's-complement is a better question. – yan Apr 13 '11 at 19:01
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    @yan: Because I know that it's going to run on a 2's-complement processor. Don't be silly. – TonyK Apr 13 '11 at 19:03
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    The point of having a (more or less) high-level language is not having to care about implementation details. A number is a number and it shouldn't matter how it's implemented. Look at any high-level language spec. Nobody requires anything about the inner workings of implementations. – user395760 Apr 13 '11 at 19:05
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    @delnan: No, there are plenty of problems that require bit-fiddling. Have you ever written a chess program? Or an arbitrary-precision floating-point library? Both of these would be much harder to write if you couldn't rely on the fact that the processor uses 2's complement arithmetic. They would be much slower too. – TonyK Apr 13 '11 at 19:10
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    @delnan: that's not true at all. The representation of unsigned integer types is hedged about by a whole bunch of requirements, the only implementation freedom is to add padding bits. The representation of signed types slightly less so, but still only 3 representations are allowed (2's complement, 1s' complement, sign-magnitude). If it were true that nobody required anything of the inner workings, then why that list of 3? – Steve Jessop Apr 13 '11 at 19:12
  • A major problem in defining something which isn't, is that compilers were built assuming that is undefined. Changing the standard won't change the compilers and reviewing those to find out where the assumption was made is a difficult task.

  • Even on 2 complement machine, you may have more variety than you think. Two examples: some don't have a sign preserving right shift, just a right shift which introduce zeros; a common feature in DSP is saturating arithmetic, there assigning an out of range value will clip it at the maximum, not just drop the high order bits.

  • +1, explains why the OP's claim "The only reason for them is to accommodate non-2's-complement" is false, which is probably the closest this question will get to a definitive answer, even if it is only to the supplementary background :-) – Steve Jessop Apr 13 '11 at 19:24
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    This is much the most helpful response to my question! But still: are there any implementations of C++ for such architectures? And are there likely to be, ever? – TonyK Apr 13 '11 at 19:32
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    @TonyK: don't forget that even today, and even though it hasn't adopted all C99 features, one of the goals of C++0x is a kind of limited "compatibility" with C. Surely there are C implementations for some of those DSPs with saturating arithmetic, and certainly could be C++ implementations without too much bother, given the flexibility of GCC or LLVM. So the fact that out-of-range assignment is implementation-defined does have practical consequences, I reckon. – Steve Jessop Apr 13 '11 at 19:38
  • This is a good point. Historically, the C++ Standard is more about getting the behavior down on paper rather than dictating what the behavior should be. So if implementations vary, then that variation should be noted in the standard. – Jeffrey L Whitledge Apr 13 '11 at 19:40
  • For what kind of architecture? Non 2's complement? -- I don't think so, AFAIK the only one still built is by Unisys and has a C compiler but not a C++ one. Saturating arithmetic? I'd not be surprised that it exists in vector extension for common architecture. – AProgrammer Apr 13 '11 at 19:40

It seems to me that, even today, if you are writing a broadly-applicable C++ library that you expect to run on any machine, then 2's complement cannot be assumed. C++ is just too widely used to be making assumptions like that.

Most people don't write those sorts of libraries, though, so if you want to take a dependency on 2's complement you should just go ahead.

  • But as AProgrammer points out, even being a two's-complement machine doesn't assure the behavior TonyK is asking about. Assignment of an out-of-range value can saturate instead of discarding high bits, and signed right-shift can round-toward-zero (add the most significant of the shifted-out bits back in) instead of round-down (discard shifted out bits). These behaviors are perfectly possible on two's-complement hardware. – Ben Voigt Apr 13 '11 at 19:33

I suppose it is because the Standard says, in 3.9.1[basic.fundamental]/7

this International Standard permits 2’s complement, 1’s complement and signed magnitude representations for integral types.

which, I am willing to bet, came along from the C programming language, which lists sign and magnitude, two's complement, and one's complement as the only allowed representations in And there sure were 1's complement systems around when C was wide-spread: UNIVACs are the most often mentioned, it seems.

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    The question is why the standard doesn't require 2's complement instead... – user395760 Apr 13 '11 at 19:05
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    Because there is simply no reason to do so. – Michael Foukarakis Apr 13 '11 at 19:10
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    @delnan - What would the standard benefit from banning specific kinds of hardware? If you want to write code for 2's complement only, you are free to do so. Why forbid everyone else from doing otherwise? – Bo Persson Apr 13 '11 at 19:13
  • @Bo @Michael: That's an answer for the OP, not for me ;) – user395760 Apr 13 '11 at 19:15
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    @Bo: the standard does ban specific kinds of hardware, or rather it demands that their C++ implementations behave like other kinds of hardware, even if doing so is inefficient. If I want 8-bit excess-127 bytes in my C++ implementation then I'm out of luck, the standard bans that. – Steve Jessop Apr 13 '11 at 19:33

Many aspects of the language standard are as they are because the Standards Committee has been extremely loath to forbid compilers from behaving in ways that existing code may rely upon. If code exists which would rely upon one's complement behavior, then requiring that compilers behave as though the underlying hardware uses two's complement would make it impossible for the older code to run using newer compilers.

The solution, which the Standards Committee has alas not yet seen fit to implement, would be to allow code to specify the desired semantics for things in a fashion independent of the machine's word size or hardware characteristics. If support for code which relies upon ones'-complement behavior is deemed important, design a means by which code could expressly demand one's-complement behavior regardless of the underlying hardware platform. If desired, to avoid overly complicating every single compiler, specify that certain aspects of the standard are optional, but conforming compilers must document which aspects they support. Such a design would allow compilers for ones'-complement machines to support both two's-complement behavior and ones'-complement behavior depending upon the needs of the program. Further, it would make it possible to port the code to two's-complement machines with compilers that happened to include ones'-complement support.

I'm not sure exactly why the Standards Committee has as yet not allowed any way by which code can specify behavior in a fashion independent of the underlying architecture and word size (so that code wouldn't have some machines use signed semantics for comparisons where other machines would use unsigned semantics), but for whatever reason they have yet to do so. Support for ones'-complement representation is but a part of that.

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