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Is there a C++ Standards compliant way to determining the structure of a 'float', 'double', and 'long double' at compile-time ( or run-time, as an alternative )?

If I assume std::numeric_limits< T >::is_iec559 == true and std::numeric_limits< T >::radix == 2, I suspect the is possible by the following rules:

  • first X-bits are the significand.
  • next Y-bits are the exponent.
  • last 1-bit is the sign-bit.

with the following expressions vaguely like:

  • size_t num_significand_bits = std::numeric_limits< T >::digits;
  • size_t num_exponent_bits = log2( 2 * std::numeric_limits< T >::max_exponent );
  • size_t num_sign_bits = 1u;

except I know

  • std::numeric_limits< T >::digits includes the "integer bit", whether or not the format actually explicitly represents it, so I don't know how to programmatically detect and adjust for this.
  • I'm guessing std::numeric_limits< T >::max_exponent is always 2^(num_exponent_bits)/2.

Background: I'm trying to overcome two issues portably:

  • set/get which bits are in the significand.
  • determine where the end of 'long double' is so I know not to read the implicit padding bits that'll have uninitialized memory.
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I just saw Question 10620601 which uses a seemingly Posix header ieee754.h that define structs with bit-field specifiers for everything. I like that idea, but I'm unsure if that's really portable. – Charles L Wilcox Mar 8 '13 at 18:47
Portable Floating-Point Bit Representation? Yes, the ASCII representation would be portable to any language and any OS. I believe you might have an XY Problem, what are you trying to do?\ – Lie Ryan Mar 8 '13 at 18:49
Yes, I'm thinking in the solution-space of my already decomposed problem. I want to set and test the payload of a signaling-nan; I want to set and use a signaling-nan as a "null value" for floating-point numbers; however, I'd like to distinguish it from other NaNs produced by the system otherwise. nan(char const*) exists only for quiet-nan, and payload format is not portable. I need to do "equality testing", but obviously operator== for any NaN on either side returns false, so I have to test the underlying binary representation, while avoiding long double's uninitialized packing-bits. – Charles L Wilcox Mar 8 '13 at 18:55
Why is the packing bits of a concern? – Mats Petersson Mar 8 '13 at 19:05
And you want this to work on IBM mainframes, PC's with SSE and x87 fpu, DEC Alpha, microcontrollers made by some unknown Taiwan company, and everything else, yes? I think you might just as well try come up with the answer to world starvation - in fact, that's probably a lot easier.... :) – Mats Petersson Mar 8 '13 at 19:18
up vote 4 down vote accepted

In short, no. If std::numeric_limits<T>::is_iec559, then you know the format of T, more or less: you still have to determine the byte order. For anything else, all bets are off. (The other formats I know that are still being used aren't even base 2: IBM mainframes use base 16, for example.) The "standard" arrangement of an IEC floating point has the sign on the high order bit, then the exponent, and the mantissa on the low order bits; if you can successfully view it as an uint64_t, for example (via memcpy, reinterpret_cast or union—`memcpy is guaranteed to work, but is less efficient than the other two), then:

for double:

uint64_t tmp;
memcpy( &tmp, &theDouble, sizeof( double ) );
bool isNeg = (tmp & 0x8000000000000000) != 0;
int  exp   = (int)( (tmp & 0x7FF0000000000000) >> 52 ) - 1022 - 53;
long mant  = (tmp & 0x000FFFFFFFFFFFFF) | 0x0010000000000000;

for `float:

uint32_t tmp;
memcpy( &tmp, &theFloat, sizeof( float ) );
bool isNeg = (tmp & 0x80000000) != 0;
int  exp   = (int)( (tmp & 0x7F800000) >> 23 ) - 126 - 24 );
long mant  = (tmp & 0x007FFFFF) | 0x00800000;

With regards to long double, it's worse, because different compilers treat it differently, even on the same machine. Nominally, it's ten bytes, but for alignment reasons, it may in fact be 12 or 16. Or just a synonym for double. If it's more than 10 bytes, I think you can count on it being packed into the first 10 bytes, so that &myLongDouble gives the address of the 10 byte value. But generally speaking, I'd avoid long double.

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I've been tinkering with a union { unsigned long words[ ( sizeof( T ) -1 ) / sizeof(unsigned long) + 1]; T value; }; to inspect the bits. – Charles L Wilcox Mar 8 '13 at 19:20
Yes, I've read that 'long double' is actually 'double' on Windows 64-bit. On my GNU/Linux 64-bit, it has the +2 packing-bytes to get to 12-bytes. – Charles L Wilcox Mar 8 '13 at 19:21
Heh, "just don't bother for long double"; I hadn't seriously considered that before. For float and double, if not is_iec559, I don't try to pack the significand with a bit-pattern; I could ignore packing the significand for long double, no matter the is_iec559ness. – Charles L Wilcox Mar 8 '13 at 19:24
@CharlesLWilcox That's a strange union. The classical union would be something like: union { unsigned char image[ sizeof(T) ]; T value }'. This still means that even on platforms with IEC, you have to consider endianness. Since IEC guarantees that double` is 64 bits, and is not implemented on any platform which doesn't have uint64_t, those are the two types I'd alias. As for how to alias: memcpy works everywhere (but is usually significantly slower); the union or the reinterpret_cast will normally work in specific situations, but require more care. – James Kanze Mar 10 '13 at 13:26
I was using unsigned long as a guess for the native word-size, for faster math. ( std::bitset on GNU/Linux happens to use this, and I was looking at that around the same time. ) Yes, the uint8_t chars[ sizeof(T) ] would be much more explicit / straightforward. – Charles L Wilcox Mar 10 '13 at 19:12

I would say that the only portable way is to store the number as a string. This is not relying on "interpreting bit patterns"

Even if you know how many bits something is, doesn't mean that it has the same representation - the exponent zero-based or biased. Is there an invisible 1 at the front of the mantissa? The same applies to all of the other parts of the number. And it gets even worse for BCD encoded or "hexadecimal" floats - these are available in some architectures...

If you are worried about uninitialized bits in a structure (class, array, etc), then use memset to set the entire structure to zero [or some other known value].

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+ mantissa representation (2's complement or sign-magnitude), special values (INFINITY, NAN), subnormal values, order of bits. And there may be some more intricacies. – Alexey Frunze Mar 8 '13 at 19:01
I really don't want to serialize to/from string just to set a specific value, and test for that value in other T's later on. (Also, setting a signaling-NaN value via scanf or operator>> may not be portable.) I need to write a function to test for this pattern in a user's T; memseting a local T, assigning the user-value to the local, then inspecting the bits seems a bit over-complicated. – Charles L Wilcox Mar 8 '13 at 19:03
Um, a generic solution is going to be even more complicated. Why not develop a platform-specific solution instead and include a check to see that this is the right platform? – Alexey Frunze Mar 8 '13 at 19:12
@AlexeyFrunze Thus my preconditions of floats really being IEEE754/IEC559, and the radix really being '2'. I'm writing a small library; useful libraries are portable. – Charles L Wilcox Mar 8 '13 at 19:14
@CharlesLWilcox If the floats are IEC, then the radix must be 2. – James Kanze Mar 8 '13 at 19:15

For posterity, this is what I ended up doing.

To generate and test for my IEEE-754 signaling-NaN values, I use this pattern for 'float' and 'double'.

#include <cstdint> // uint32_t, uint64_t
#include <limits> // numeric_limits

union IEEE754_Float_Union
    float value;
    uint32_t bits;

float generate_IEEE754_float()
    IEEE754_Float_Union u = { -std::numeric_limits< float >::signaling_NaN() };
    size_t const num_significand_bits_to_set = std::numeric_limits< float >::digits
                                               - 1 // implicit "integer-bit"
                                               - 1; // the "signaling-bit"
    u.bits |= ( static_cast< uint32_t >( 1 ) << num_significand_bits_to_set ) - 1;
    return u.value;

bool test_IEEE754_float( float const& a_r_val )
    IEEE754_Float_Union const u = { a_r_val };
    IEEE754_Float_Union const expected_u = { generate_IEEE754_float() };
    return u.bits == expected_u.bits;

For 'long double', I use the 'double' functions with casting. Specifically, I generate the 'double' value and cast it to 'long double' before it's returned, and I test the 'long double' by casting to 'double' then testing that value. My idea is that, while the 'long double' format can vary, casting a 'double' into a 'long double', then casting it back to 'double' later on should be consistent, ( i.e. not loose any information. )

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