Is the behaviour of casting a negative double to unsigned int defined in the C standard? Different behaviour on ARM vs. x86

Question

I have code that runs on different platforms that seems to get different results. I am looking for a proper explanation.

I expected casting to unsigned to work the same for float or double as for int¹.

Windows :

double dbl = -123.45; 
int d_cast = (unsigned int)dbl; 
// d_cast == -123

WinCE (ARM):

double dbl = -123.45; 
int d_cast = (unsigned int)dbl; 
// d_cast == 0

EDIT:

Thanks for pointing in the right direction.

fix workaround

double dbl = -123.45; 
int d_cast = (unsigned)(int)dbl; 
// d_cast == -123
// works on both. 

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Footnote 1: Editor's note: converting an out-of-range unsigned value to a signed type like int is implementation defined (not undefined). C17 § 6.3.1.3 - 3.

So the assignment to d_cast is also not nailed down by the standard for cases where (unsigned)dbl ends up being a huge positive value on some particular implementation. (That path of execution contains UB so ISO C is already out the window in theory). In practice compilers do what we expect on normal 2's complement machines and leave the bit-pattern unchanged.

Answer 1

No

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This conversion is undefined and therefore not portable.

C99/C11 6.3.1.4

When a finite value of real floating type is converted to an integer type other than _Bool, the fractional part is discarded (i.e., the value is truncated toward zero). If the value of the integral part cannot be represented by the integer type, the behavior is undefined.

According to C11 6.3.1.4 footnote 61:

The remaindering operation performed when a value of integer type is converted to unsigned type need not be performed when a value of real floating type is converted to unsigned type. Thus, the range of portable real floating values is (−1, Utype_MAX+1).

Answer 2

C and C++ clearly should define (unsigned int)negativeFloat as equivalent to (unsigned int)(int)negativeFloat. Leaving it undefined is a disaster, especially now that x86 and ARM have diverged. ARM should follow x86 and work around this huge let-down in the language specification.

Answer 3

If there were some platform where the most efficient method of converting values in the range strictly between -1 and UINT_MAX+1.0 would be incapable of behaving meaningfully with negative values, and whose customers wouldn't care about behavior with negative values, the authors of the Standard wouldn't have wanted to mandate that implementations use a less efficient means of performing the conversion. Further, implementations were probably inconsistent in how they handled conversion of negative fractional values [including, incidentally, those between 0 and -1]. For example, it's hardly implausible that an implementation might process someUnsigned = someFloat; as someUnsigned = (someFloat < 0) ? (UINT_MAX+1.0)+someFloat : someFloat;. The classification of the behavior as UB doesn't imply any judgment that (unsigned)(-1.0f) shouldn't be expected to yield UINT_MAX, but rather a waiver of judgment over which cases various kinds of implementations should or should not be expected to process predictably.