The C standard, which C++ relies on for these matters as well, as far as I know, has the following section:

When a value of integer type is converted to a real floating type, if the value being converted can be represented exactly in the new type, it is unchanged. If the value being converted is in the range of values that can be represented but cannot be represented exactly, the result is either the nearest higher or nearest lower representable value, chosen in an implementation-defined manner. If the value being converted is outside the range of values that can be represented, the behavior is undefined.

Is there any way I can check for the last case? It seems to me that this last undefined behaviour is unavoidable. If I have an integral value i and naively check something like

i <= FLT_MAX

I will (apart from other problems related to precision) already trigger it because the comparison first converts i to a float (in this case or to any other floating type in general), so if it is out of range, we get undefined behaviour.

Or is there some guarantee about the relative sizes of integral and floating types that would imply something like "float can always represent all values of int (not necessarily exactly of course)" or at least "long double can always hold everything" so that we could do comparisons in that type? I couldn't find anything like that, though.

This is mainly a theoretical exercise, so I'm not interested in answers along the lines of "on most architectures these conversions always work". Let's try to find a way to detect this kind of overflow without assuming anything beyond the C(++) standard! :)

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    64-bit IEEE floating-point can represent any <=32-bit integer without loss of precision, and 32-bit IEEE floating-point can represent any <=16-bit integer. I'm not sure there is any other guarantee. Generally-speaking, a floating-point type with a significand of N bits or more can exactly represent any integer type of N bits or fewer. – cdhowie Aug 28 '17 at 20:33
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    The question is funny. I do not think it can be solved in generic manner. For starters, Standard doesn't even mandate IEEE 754 for floats. I think, you will end up with implementation-specific logic, which knows how floats are represented and what their values are. – SergeyA Aug 28 '17 at 20:42
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    @cdhowie not forgetting that the floating point significand has one more bit than is stored, since the normalised significand's m.s. bit is always 1 and so is implied (except for a value 0). – Weather Vane Aug 28 '17 at 21:29
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    @old_timer uintmax_t as a 128-bit type having a value of just exceeding FLT_MAX (overflow) is a real possibility and is a reasonable concern for OP writing code that uses such wide integers and narrow FP. – chux - Reinstate Monica Aug 28 '17 at 21:51
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    @curiousguy you didnt read the whole statement you cant overflow a float from an integer conversion. now granted I did demonstrate that with a half precision, but single on up using typical integers (32 bit, 64 bit) you wont overflow. You can/will lose precision but that is something different, which is the key here that folks are confused about. The quoted text is easy to understand as well as the situations that cause it...but implementation defined as one would expect, otherwise they would have to write hundreds of more pages... – old_timer Aug 30 '17 at 2:53

Detect overflow when converting integral to floating types

FLT_MAX, DBL_MAX are at least 1E+37 per the C spec, so all integers with |values| of 122 bits or less will convert to a float without overflow on all compliant platforms. Same with double

To solve this in the general case for integers of 128/256/etc. bits, both FLT_MAX and some_big_integer_MAX need to be reduced.

Perhaps by taking the log of both. (bit_count() is a TBD user code)

if(bit_count(unsigned_big_integer_MAX) > logbf(FLT_MAX)) problem();

Or if the integer lacks padding

if(sizeof(unsigned_big_integer_MAX)*CHAR_BIT > logbf(FLT_MAX)) problem();

Note: working with a FP function like logbf() may produce an edge condition with the exact integer math with an incorrect compare.

Macro magic can use obtuse tests like the following that takes advantage the BIGINT_MAX is certainly a power-of-2 minus 1 and FLT_MAX division by a power of 2 is certainly exact (unless FLT_RADIX == 10).

This pre-processor code will complain if conversion from a big integer type to float will be inexact for some big integer.

#define POW2_61 0x2000000000000000u  
#if BIGINT_MAX/POW2_61 > POW2_61
  // BIGINT is at least a 122 bit integer 
  #define BIGINT_MAX_PLUS1_div_POW2_61  ((BIGINT_MAX/2 + 1)/(POW2_61/2))
  #if BIGINT_MAX_PLUS1_div_POW2_61 > POW2_61
    #warning TBD code for an integer wider than 183 bits
    _Static_assert(BIGINT_MAX_PLUS1_div_POW2_61 <= FLT_MAX/POW2_61, 
        "bigint too big for float");

[Edit 2]

Is there any way I can check for the last case?

This code will complain if conversion from a big integer type to float will be inexact for a select big integer.

Of course the test needs to occur before the conversion is attempted.

Given various rounding modes or a rare FLT_RADIX == 10, the best that can readily be had is a test that aims a bit low. When it is true, the conversion will work. Yet a vary small range of of big integers that report false on the below test do convert OK.

Below is a more refined idea that I need to mull over for a bit, yet I hope it provides some coding idea for the test OP is looking for.

#define POW2_60 0x1000000000000000u
#define POW2_62 0x4000000000000000u
#define MAX_FLT_MIN 1e37
#define MAX_FLT_MIN_LOG2 (122 /* 122.911.. */)

bool intmax_to_float_OK(intmax_t x) {
#if INTMAX_MAX/POW2_60 < POW2_62
  (void) x;
  return true; // All big integer values work
#elif INTMAX_MAX/POW2_60/POW2_60 < POW2_62
  return x/POW2_60 < (FLT_MAX/POW2_60) 
#elif INTMAX_MAX/POW2_60/POW2_60/POW2_60 < POW2_62
  return x/POW2_60/POW2_60 < (FLT_MAX/POW2_60/POW2_60) 
  #error TBD code

Here's a C++ template function that returns the largest positive integer that fits into both of the given types.

template<typename float_type, typename int_type>
int_type max_convertible()
    static const int int_bits = sizeof(int_type) * CHAR_BIT - std::is_signed<int_type>() ? 1 : 0;
    if ((int)ceil(std::log2(std::numeric_limits<float_type>::max())) > int_bits)
        return std::numeric_limits<int_type>::max();
    return (int_type) std::numeric_limits<float_type>::max();

If the number you're converting is larger than the return from this function, it can't be converted. Unfortunately I'm having trouble finding a combination of types to test it with, it's very hard to find an integer type that won't fit into the smallest floating point type.

  • "largest representable integer" <-- I believe what you mean is it returns the largest representable integer that fits into both of the given types for which all smaller integers are also representable and fit into the given types. – cdhowie Aug 28 '17 at 22:33
  • @cdhowie I've changed the wording of that statement. Do I really need to explicitly state that smaller integers would also fit? It seems that should follow automatically. – Mark Ransom Aug 28 '17 at 22:37
  • I don't think it does follow. I'm sure there are larger integers that can be exactly represented, but are not consecutive integers. – cdhowie Aug 28 '17 at 23:41
  • @cdhowie OK, I see what you're saying now. The question specifies 3 different ranges: the range where all consecutive values can be represented, the range where some rounding can be expected, and the range that causes undefined behavior. An answer was only requested for the third case, and that's what this is. – Mark Ransom Aug 29 '17 at 0:34
  • Fair point, for some reason I thought the question was asking about the second case. Oops. – cdhowie Aug 29 '17 at 15:24

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