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In some C99 code, I need to check whether variable i is in the interval [0, max] where max is known to be positive. The problem is that the type of the variable is allowed to be both signed and unsigned (by changing a typedef). How does one best check that the variable is in the interval?

The straightforward approach would be:

bool is_in_interval(my_type i, my_type max) {
    assert(max > 0);
    return (i >= 0 && i <= max);
}

This will work fine when we have typedef int my_type;. But when my_type is unsigned (i.e., typedef unsigned int my_type;), i >= 0 is always true and compilers will (rightly) warn for it, which I want to avoid. (I don't want to turn off that warning since it's useful when such comparisons actually are unintended, and just ignoring compiler warnings is not a good idea.)

My current idea is to cast i to an unsigned type and just check the upper bound:

bool is_in_interval(my_type i, my_type max) {
    assert(max > 0);
    return ((size_t) i <= (size_t) max);
}

If the signed type has a two's complement representation, any negative value should be greater than max once cast to the unsigned version, right? If so, this should work. I'm, however, uncertain whether this is an advisable approach. Is it, for example, safe to assume that signed types use two's complement on all platforms? Is there some better way to do this?

share|improve this question
    
This would not work when your signed testing value, interpreted as unsigned, could be greater than (unsigned)MAX/2. Can that be the case? (Um. Maybe I mean less than.) – Rad Lexus Feb 14 at 4:06
2  
I pretty sure it's guaranteed that a negative value cast to a compatible unsigned type will be greater than any positive value for the original type. However, you'll get people moaning about "weird code" if you do that. – sh1 Feb 14 at 4:10
    
@Jongware Sorry, I don't quite get what you mean. MAX is not the limit of the type (e.g., INT_MAX or UINT_MAX). Using capital letters was misleading (It's changed now). – Fredrik Savje Feb 14 at 4:11
1  
@JohnColeman I don't have any religious aversion against ignoring compiler warnings. However, I think it's a good rule of thumb that there should be none. Otherwise, one has to keep track of the files and line numbers where warnings are OK and where they're not. The risk that one misses a real problem in that case seems quite high. – Fredrik Savje Feb 14 at 4:25
1  
A C implementation can have integer types 'wider' (informally, larger) than size_t and if so that cast can change the value and give you a wrong result. uintmax_t from <stdint.h> portably avoids this (in C99 and later, but you said C99). OTOH 2sC is not an issue; converting signed integer to unsigned in C is defined as effectively adding or subtracting 2 up w even on a (very very rare) 1sC or S&M machine. – dave_thompson_085 Feb 14 at 12:46
up vote 7 down vote accepted

Check against 0 and max. Yet avoid a direct >= 0 test.

Casting is a problem as it may narrow the value in some implementation defined way.

bool is_in_interval(my_type i, my_type max) {
  // first, take care of the easy case
  if (i > max) return false;
  if (i > 0) return true;
  return i == 0;
}

I will ponder this some more too.

share|improve this answer
    
Thank you! Could you elaborate on "Casting is a problem as it may narrow the value in some implementation defined way"? Don't quite understand how you mean. – Fredrik Savje Feb 14 at 4:32
1  
@Fredrik Savje Casting a long long (maybe the type of my_type) to unsigned is well defined, yet likely loses some range and ((size_t) i <= (size_t) max) is then meaningless as the cast may have changed max value but not i. – chux Feb 14 at 4:37
1  
@sh1 2 problems with that approach: A casted negative i may or may not exceed the casted max - ti be >, that assumes a certain integer layout that, though common, is not specified by C.. Systems do support, in a weaselly sort of way, integer types that exceed uintmax_t. (e.g. 128 bit types without calling them "integer") Although I suspect your idea will work 99.999% of the time. – chux Feb 14 at 5:06
1  
@Fredrik Savje I see 4 approaches: preprocessor, hiding >= in code (as above), _Generic(), 2nd level function is_in_interval2(i, 0, max). Preprocessor does not understand my_type as it only uses intmax_t. Hiding >= with a sequent point. (Pedantic, volatile my_type j = i; if (j > 0) return true; return j == 0;. _Generic() would work well except it is difficult to enumerate all signed/unsigned types in a portable fashion. – chux Feb 14 at 15:18
1  
@chux, That problem exists not just for nonstandard int types, but also for float and double. I think that for UINTMAX_MAX to be less than twice INTMAX_MAX requires that uintmax_t have a junk bit. I admit it's possible for any type, but most plausible for 16 bit types (DSPs). – sh1 Feb 14 at 17:11

I think this should shut the compiler up:

bool is_in_interval(my_type i, my_type max) {
  my_type zero = 0;
  assert(max > 0);
  return (zero <= i && i <= max);
}
share|improve this answer
    
It will shut some compilers up, but not all. Compilers vary in whether testing against a declared const variable will trigger warnings like "condition always true" or "condition always false". – Peter Feb 14 at 5:01
    
@Peter I see, thanks! Then it became less attractive. – Fredrik Savje Feb 14 at 5:06
    
I could suggest volatile instead of const, but it might be better to find the specific compiler's inline annotation to disable the warning. – sh1 Feb 14 at 5:08
    
Perhaps volatile signed char zero = 0;? – chux Feb 14 at 15:21
    
@chux, I've used volatile in situations like this before, but specifically to convince the debugger to de-optimise the code so that I could edit the value in the debugger. So I know that in at least some compilers it would imply a performance penalty. – sh1 Feb 14 at 17:05

Maybe this is another straightforward approach:

bool is_in_interval(my_type i, my_type max) {
    assert(max > 0);
    if ((my_type)-1 > 0)
        return (i <= max); // my_type is unsigned
    else
        return (0 <= i && i <= max); // my_type is signed
}
share|improve this answer
    
Will not if ((my_type)-1 > 0) create a warning as it is always true or false. Much like OP's " always true and compilers will (rightly) warn"? – chux Feb 14 at 4:43
    
Well, clang does give me an warning, but it's on return (0 <= i && i <= max); // my_type is signed, saying comparison of 0 <= unsigned expression is always true. – sun qingyao Feb 14 at 5:10

A simple solution is to do a 2-sided test.

The only attribute really lost is modest efficiency/performance. No other problems.

Although OP has certainly considered this, any solution should be weighed against this as a reference.

bool is_in_interval2(my_type i, my_type min, my_type max) {
  return i >= min && i <= max;
}

// Could make this a macro or inline
bool is_in_interval(my_type i, my_type max) {
  return is_in_interval2(i, 0, max);
}
share|improve this answer

If your compiler supports it, I believe the cleanest solution would be to keep the code as is, but to use a #pragma directive to locally disable the spurious warning. For example, for GCC 4.6.4+, the following would do the trick:

bool is_in_interval(my_type i, my_type max) {
    assert(max > 0);
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wtype-limits"
    /* i >= 0 could warn if my_type is unsigned */
    return (i >= 0 && i <= max);
#pragma GCC diagnostic pop
}

Apparently, the exact same #pragmas should work for Clang too, since it imitates GCC's syntax. Other compilers may have similar syntax (e.g. #pragma warning( disable: ... ) for Visual C/C++), and it should be possible to use preprocessor directives to select the appropriate #pragmas for each compiler.

The main downside of this method is aesthetic — it litters the code with ugly #pragmas. That said, I would consider that preferable to deliberately obfuscating (and possibly de-optimizing) your code just to avoid a compiler warning. At least, with the #pragmas, it's clear to the next programmer that reads the code why it's written the way it is.


To make this cleaner and more portable, you can use the C99 _Pragma() operator to define macros that disable and re-enable the warnings, e.g. like this:

#if __GNUC__ * 10000 + __GNUC_MINOR__ * 100 + __GNUC_PATCHLEVEL__ >= 40604
#  define NO_TYPE_LIMIT_WARNINGS \
       _Pragma("GCC diagnostic push") \
       _Pragma("GCC diagnostic ignored \"-Wtype-limits\"")
#  define RESTORE_WARNINGS \
       _Pragma("GCC diagnostic pop")
/* Add checks for other compilers here! */
#else
#  define NO_TYPE_LIMIT_WARNINGS /* nothing */
#  define RESTORE_WARNINGS /* nothing */
#endif

and use them like this:

bool is_in_interval(my_type i, my_type max) {
    assert(max > 0);
    NO_TYPE_LIMIT_WARNINGS; /* i >= 0 could warn if my_type is unsigned */
    return (i >= 0 && i <= max);
    RESTORE_WARNINGS;
}

Alternatively, if you wanted to support pre-C99 compilers, you could create a pair of header files (without any include guards!) named something like warnings_off.h and warnings_restore.h that contain the appropriate #pragma for each compiler, and then bracket the code you want to silence warnings for with:

#include "warnings_off.h"
/* ...code that emits spurious warnings here... */
#include "warnings_restore.h"
share|improve this answer
    
I like this idea yet see a large down side of portability: There are lots of non-gcc C compiler's (and programmers), including maybe one of OP's, that would need to re-write/#ifdef code. – chux Feb 14 at 15:34
    
Thank you! In some sense, this probably is the "correct" way to do it. All solutions presented so far are basically ways to trick the compiler not to warn for something it should warn for -- the obvious solution would be to just temporary disable the warning. The problem here is that I'm writing a small C library so I cannot rely on a specific compiler. – Fredrik Savje Feb 14 at 20:15

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