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Testing a couple of compilers (Comeau, g++) confirms that the result of a bitwise operator of some "integer type" is an int:

void foo( unsigned char );
void foo( unsigned short );

unsigned char a, b;

foo (a | b);

I would have expected the type of "a | b" to be an unsigned char, as both operands are unsigned char, but the compilers say that the result is an int, and the call to foo() is ambiguous. Why is the language designed so that the result is an int, or is this implementation dependent?

Thanks,

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6 Answers 6

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This is in fact standard C++ behavior (ISO/IEC 14882):

5.13/1 Bitwise inclusive OR operator

The usual arithmetic conversions are performed; the result is the bitwise inclusive OR function of its operands. The operator applies only to integral or enumeration operands.

5/9 Usual arithmetic conversions

Many binary operators that expect operands of arithmetic or enumeration type cause conversions and yield result types in a similar way. The purpose is to yield a common type, which is also the type of the result. This pattern is called the usual arithmetic conversions, which are defined as follows:

  • If either operand is of type long double, the other shall be converted to long double.
  • Otherwise, if either operand is double, the other shall be converted to double.
  • Otherwise, if either operand is float, the other shall be converted to float.
  • Otherwise, the integral promotions shall be performed on both operands.
  • ...

4.5/1 Integral Promotions

An rvalue of type char, signed char, unsigned char, short int, or unsigned short int can be converted to an rvalue of type int if int can represent all the values of the source type; otherwise, the source rvalue can be converted to an rvalue of type unsigned int.

I think it has to do with int supposedly being the "natural" size for the execution environment to allow for efficient arithmetic (see Charles Bailey's answer).

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    Looks to me like it says can be. IOW: If your compiler may or may not promote to int.
    – T.E.D.
    Jul 28, 2010 at 21:44
  • @T.E.D.: It say "can be", because the target type can be either int or unsigned int. That the only "can be" that exists here. As for the promotion itself, it is always unconditionally required.
    – AnT
    Jul 28, 2010 at 21:49
  • @AndreyT - That isn't true. "... can be converted ... if int can represent all the values of the source type; otherwise ... can be converted to ... unsigned int". Since it says "can be" in the second option, the entire conversion is optional. Jul 28, 2010 at 21:58
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    @Merlyn Morgan-Graham: No, all "can be"s in this text come from the dependence of this part of specification on such implementation details as ranges of "smaller" types. But the promotion itself is unavoidable. C/C++ never perform arithmetic on types smaller than int/unsigned int.
    – AnT
    Jul 28, 2010 at 22:22
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    @T.E.D, Steve Jessop, AndreyT: Oops, missed the "Otherwise, the integral promotions shall be performed". To ape Jeff Foxworthy, "Your language might have a complexity problem if..." Jul 28, 2010 at 23:05
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I would have expected the type of "a | b" to be an unsigned char, as both operands are unsigned char,

My reading of some beginner C books in past left the impression that bitwise operators were left in the language solely for the purpose of the system programming and generally should be avoided.

The operators are performed by the CPU itself. CPU uses for operands registers (which are surely larger than char) and thus compiler cannot know how much bits of a register would be affected by the operation. To not to loose the full result of the operation, compiler upcasts the result to the proper operation. AFAICT.

Why is the language designed so that the result is an int, or is this implementation dependent?

Bit-level representation of data types is in fact implementation defined. That might be the reason why apparently bit-wise operations are also implementation defined.

Though C99 defines in 6.2.6.2 Integer types how they should appear and behave (and later how bitwise operations should work) the particular chapter gives a lot of freedom to the implementation.

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It seems this is the same thing as in Java:

Short and char (and other integers smaller than an int) are weaker types than int. Every operation on these weaker types is therefore automatically unboxed into an int.

If you really want to get a short, you will have to typecast it.

Unfortunately I can't tell you why this was done, but it seems this is a relatively common language decision...

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  • short to int conversion is not 'unboxing'. Unboxing is such things as Integer to int (the reverse being 'boxing'). short to int is simply an implicit cast (as opposed to an explicit cast: int a = 123; short b = (short)a;).
    – Brian S
    Jul 28, 2010 at 21:52
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Isn't short the same as short int? in the same way that long is synonymous with int. eg. a short is an int taking up less memory then a standard int?

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    long is not synonymous with int. The relationship between the types is that the size of char <= short <= int <= long, with additional rules stipulating the minimum size of each of the types. Jul 28, 2010 at 21:41
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int is supposed to be the natural word size for any given machine architecture and many machines have instructions that only (or at least optimally) perform arithmetic operations on machine words.

If the language were defined without integer promotion, many multistep calculations which could otherwise naturally be mapped directly into machine instructions might have to be interspersed with masking operations performed on the intermediates in order to generate 'correct' results.

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  • Personally I still question this. Either the intermediate masking changes the final result, or it doesn't. When it doesn't, the compiler could skip it. When it does, the 'no arithmetic smaller than int' rule introduces "surprising behaviour" - fast results which are "wrong" w.r.t the types of the operands. An alternative would be just not to define any operators that would be "too slow" in their reasonably "expected" meanings. Of course C hackers back in the day didn't have quite the same expectations of usability we do now ;-) Jul 28, 2010 at 21:50
  • ... a more convincing argument to me is that if you're doing arithmetic on shorts, you're bound to need to check for overflow sooner or later, so the compiler might as well save you from yourself. Jul 28, 2010 at 21:54
  • @Steve: In other words, all the calculations could be done in int by the as-if rule? Jul 28, 2010 at 21:56
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    @David: well, if the only opcodes available are for ints, then the calculations would be done using ints and then massaged into shape. That's not precisely the result of the 'promote to at least int' rule, though. If a and b are unsigned short of width 16 bits, the question at stake is whether (a + b) & 0x10000 can ever be non-zero. With the 'promote to at least int' rule it can, if all we had was the as-if rule with "correct" short arithmetic then of course it can't. So actually, the `promote to int' rule has created a slowdown in this example ;-) Jul 28, 2010 at 22:14
  • @Steve - I'm sure we've all overflowed 32 bits and even 64 bits before. After all, all it takes is a factorial, and we've all done that if only as a kind of hello world. So - doesn't your logic argue that all integers should be promoted to arbitrary precision integers to save us from ourselves? And after that - well, maybe the truncating division behaviour is surprising. Maybe we should promote everything to an arbitrary precision rational library? But then, what if someone takes the square root of 2, then squares the result... maybe we need symbolics to save us from ourselves?
    – user180247
    Jul 28, 2010 at 22:38
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Neither C nor C++ ever perform any arithmetic operations on types smaller than int. Any time you specify a smaller operand (any flavor of char or short), the operand gets promoted to either int or unsigned int, depending on the range.

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