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The C and C++ standards stipulate that, in binary operations between a signed and an unsigned integer of the same rank, the signed integer is cast to unsigned. There are many questions on SO caused by this... let's call it strange behavior: unsigned to signed conversion, C++ Implicit Conversion (Signed + Unsigned), A warning - comparison between signed and unsigned integer expressions, % (mod) with mixed signedness, etc.

But none of these give any reasons as to why the standard goes this way, rather than casting towards signed ints. I did find a self-proclaimed guru who says it's the obvious right thing to do, but he doesn't give a reasoning either: http://embeddedgurus.com/stack-overflow/2009/08/a-tutorial-on-signed-and-unsigned-integers/.

Looking through my own code, wherever I combine signed and unsigned integers, I always need to cast from unsigned to signed. There are places where it doesn't matter, but I haven't found a single example of code where it makes sense to cast the signed integer to unsigned.

What are cases where casting to unsigned in the correct thing to do? Why is the standard the way it is?

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    Pretend its the 1970s - think Disco. Signed comes in 3 varieties, 2's complement, 1's complement and signed magnitude. Unsigned comes in only 1 variety. Rules about mixed types are bad enough. Yet by going to signed type, the result becomes more complex as the rules need 3 variants destinations rather than 1 when going to unsigned. – chux Apr 11 '17 at 3:29
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    @chux, I think the reasoning might be related to that. But why would you need three rules? If casting -1 to unsigned can be done in a single, well-defined way across the 3 varieties of signed ints, why can't casting 0xFFFF to unsigned be done in a single, well-defined way? (Note there I'm thinking of 16-bit ints, since it's the 70's and all.) – Cris Luengo Apr 11 '17 at 3:37
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    The C language - where this rule was invented, as others have said - there were only a few data structures - naked arrays, structs, and pointers - and that matched the simple machine addressing modes at the time - things like indexed, indirect, base+displacement, base+displacement+index. Now .. it is true that the index addressing modes in standard machines at the time would take signed integers ... but it was also true that the programmers of the time didn't often use negative numbers to index ... and they did need the 2x range of unsigned on their 16-bit machines (esp. in fields of words) – davidbak Apr 11 '17 at 3:40
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    Chris: The standard only guarantees that an unsigned value has as many value bits as a signed value of the same rank, not that the sign bit is reinterpreted as a value bit. So you could handle a non-2s-complement architecture by forcing the sign bit to positive for unsigned values, thus restricting the range of representable values to the range of representable positive values in the signed type. This makes both conversion s simple (unsigned to signed becomes a no-op or a mask). But it also means that the signed type will always be chosen for the standard conversion. – rici Apr 11 '17 at 4:15
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    "I always need to cast from unsigned to signed. " - bear in mind that this is non-portable when the unsigned has a value greater than the maximum of the signed type . The compiler warns for a reason; by casting here you are saying "Oh that will never happen" – M.M Apr 11 '17 at 6:19
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Casting from unsigned to signed results in implementation-defined behaviour if the value cannot be represented. Casting from signed to unsigned is always modulo two to the power of the unsigned's bitsize, so it is always well-defined.

The standard conversion is to the signed type if every possible unsigned value is representable in the signed type. Otherwise, the unsigned type is chosen. This guarantees that the conversion is always well-defined.


Notes

  1. As indicated in comments, the conversion algorithm for C++ was inherited from C to maintain compatibility, which is technically the reason it is so in C++.

  2. It has been suggested that the decision in the standard to define signed to unsigned conversions and not unsigned to signed conversion is somehow arbitrary, and that the other possible decision would be symmetric. However, the possible conversion are not symmetric.

    In both of the non-2's-complement representations contemplated by the standard, an n-bit signed representation can represent only 2n−1 values, whereas an n-bit unsigned representation can represent 2n values. Consequently, a signed-to-unsigned conversion is lossless and can be reversed (although one unsigned value can never be produced). The unsigned-to-signed conversion, on the other hand, must collapse two different unsigned values onto the same signed result.

    In a comment, the formula sint = uint > sint_max ? uint - uint_max : uint is proposed. This coalesces the values uint_max and 0; both are both mapped to 0. That's a little weird even for non-2s-complement representations, but for 2's-complement it's unnecessary and, worse, it requires the compiler to emit code to laboriously compute this unnecessary conflation. By contrast the standard's signed-to-unsigned conversion is lossless and in the common case (2's-complement architectures) it is a no-op.

  • "Casting from unsigned to signed results in the undefined behaviour if the value cannot be represented." Nope. – Baum mit Augen Apr 11 '17 at 3:31
  • But the one cast is defined and the other isn't because it's written like that in the standard. They could have defined the cast to signed int, if they'd wanted, or? (btw: downvote not mine) – Cris Luengo Apr 11 '17 at 3:33
  • Keeping the -1, as this is certainly not why the C++ standards used that definition. – Baum mit Augen Apr 11 '17 at 3:52
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    @chris: the restriction comes frim the assumption that some architectures will trap overflow, and the standard has traditionally avoided specifications which would impose extra checks to avoid traps. – rici Apr 11 '17 at 3:52
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    "The standard conversion is to the signed type if every possible unsigned value is representable in the signed type. Otherwise, the unsigned type is chosen. This guarantees that the conversion is always well-defined." Also, that reasoning is nonsense. When writing a standard, you could make the opposite result well-defined just as well. – Baum mit Augen Apr 11 '17 at 4:00
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This is sort of a half-answer, because I don't really understand the committee's reasoning.

From the C90 committee's rationale document: https://www.lysator.liu.se/c/rat/c2.html#3-2-1-1

Since the publication of K&R, a serious divergence has occurred among implementations of C in the evolution of integral promotion rules. Implementations fall into two major camps, which may be characterized as unsigned preserving and value preserving. The difference between these approaches centers on the treatment of unsigned char and unsigned short, when widened by the integral promotions, but the decision has an impact on the typing of constants as well (see §3.1.3.2).

... and apparently also on the conversions done to match the two operands for any operator. It continues:

Both schemes give the same answer in the vast majority of cases, and both give the same effective result in even more cases in implementations with twos-complement arithmetic and quiet wraparound on signed overflow --- that is, in most current implementations.

It then specifies a case where ambiguity of interpretation arises, and states:

The result must be dubbed questionably signed, since a case can be made for either the signed or unsigned interpretation. Exactly the same ambiguity arises whenever an unsigned int confronts a signed int across an operator, and the signed int has a negative value. (Neither scheme does any better, or any worse, in resolving the ambiguity of this confrontation.) Suddenly, the negative signed int becomes a very large unsigned int, which may be surprising --- or it may be exactly what is desired by a knowledgable programmer. Of course, all of these ambiguities can be avoided by a judicious use of casts.

and:

The unsigned preserving rules greatly increase the number of situations where unsigned int confronts signed int to yield a questionably signed result, whereas the value preserving rules minimize such confrontations. Thus, the value preserving rules were considered to be safer for the novice, or unwary, programmer. After much discussion, the Committee decided in favor of value preserving rules, despite the fact that the UNIX C compilers had evolved in the direction of unsigned preserving.

Thus, they consider the case of int + unsigned an unwanted situation, and chose conversion rules for char and short that yield as few of those situations as possible, even though most compilers at the time followed a different approach. If I understand right, this choice then forced them to follow the current choice of int + unsigned yielding an unsigned operation.

I still find all of this truly bizarre.

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    Cris: That reasoning is with respect to a different issue. I was going to include it in my answer but you asked specifically about the conversion between signed and unsigned int, whereas the debate you quote is about the promotion of unsigned types narrower than int. This didn't arise in K&R C because K&R C didn't have unsigned integers other than unsigned int (and bitfields, but that's another kettle of fish). The committee didn't actually care much about signed + unsigned; the problematic case is signed < unsigned (also division, but in practice that's rare). – rici Apr 12 '17 at 19:21
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    because most implementations are/were 2s-complement with implicitly modular arithmetic. So in the common case, there was no difference in observed behaviour with arithmetic operators other than division-like operators. For comparison operators, either converting signed to unsigned or unsigned to (modular) signed is really bad. (The solution would be (in K&R) to convert both to (signed) long but that that would need to be the programmers decision.) – rici Apr 12 '17 at 19:49
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    Anyway, as I said earlier, the decision that signed->unsigned is well-defined and unsigned->signed is implementation-dependent had already been made. You can argue that a different decision could have been made, but there were a lot of factors militating for this particular decision. You could also argue that C should never have tried to accommodate non-2s-complement machines; in retrospect, that might be reasonable but at the time the future did not seem so one-dimensional. From the beginning unsigned was intended to be purely binary 2s complement. – rici Apr 12 '17 at 19:51
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    It's worth noting that the probably most prominent non-2s complement machine at the time -- the IBM 7090/7094 -- used sign-magnitude representation for arithmetic but also had unsigned carry-propagating addition (and used an unsigned modular adder for address computation as well). So it could have accommodated a C implementation with a single unsigned width and sign-magnitude signed types. But afaik, no C implementation was every written for it. – rici Apr 12 '17 at 19:54
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    The reason why unsigned-preserving is generally better is that it is easier/cleaner to write correct mixed operations. For example, comparing and signed and unsigned value correctly for all cases becomes s < 0 || s < u or s >= 0 && s > u. Both of those rely on the fact that the second comparison converts signed to unsigned if the unsigned to signed conversion would overflow. – Chris Dodd Apr 13 '17 at 17:13

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