I recently wrote some code that uses memcpy to unpack float/double to unsigned integers of the appropriate width, and then uses some bit-shifting to separate the sign bit from the combined significand/exponent.

Note: For my use case, I don't need to separate the latter two parts from eachother, but I do need them in the correct order i.e: {sign, (exponent, significand)}, with the latter tuple packed as an unsigned int of sufficient width.

My code is working fine, thoroughly tested and no trouble; however I was a bit alarmed to discover that IEEE-754 doesn't specify the endianness of its binary interchange formats —which to my understanding, means there is a rare possibility that my bit-shifting may be incorrect in the rare occasions where float endiannessinteger endianness.

Based on the answered question here, my assumption is that given that bit-shifting is independent of actual endianness in storage, I only need to worry about whether the endianness of my floats matches that of my ints.
I devised the following code loosely following that in the linked answer, but avoiding the use of type-punning through pointer casts, which seems like unspecified/undefined behaviour territory to me:

#include <cstdint>
#include <cstring>

// SAME means "same as integer endianness"
enum class FloatEndian { UNKNOWN, SAME, OPPOSITE, };

FloatEndian endianness() {
    float check = -0.0f; // in IEEE-754, this should be all-zero significand and exponent with sign=1
    std::uint32_t view;
    std::memcpy(&view, &check, sizeof(check));
    switch (view) {
    case 0x80000000: // sign bit is in most significant byte
        return FloatEndian::SAME;
    case 0x00000080: // sign bit is in least significant byte
        return FloatEndian::OPPOSITE;
    default: // can't detect endianness of float
        return FloatEndian::UNKNOWN;

If I ensure that my floats are indeed IEEE-754 with std::numeric_limits<T>::is_iec559, is my approach a robust and portable way of making sure I get the floats "the right way round" when I chop them up?

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    I suppose we could even imagine a machine where floating-point numbers are mixed endian, where the sign bit is in (say) the least significant byte, but the other bytes are ordered in some other fashion. Jul 31 at 21:42
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    @chtz why would you not rely on any runtime detection? (as an aside, I would prefer to do it at compile-time —this can be done if C++20's bit_cast() is used instead of memcpy, I've tested it on Godbolt.org but I don't have library support for it on the currently installed toolchain I have on my dev machine)
    – saxbophone
    Jul 31 at 22:19
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    @saxbophone see mixed endian. The digits in 0123, 3210, 2301 means the byte number
    – phuclv
    Aug 1 at 1:31
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    @MaximEgorushkin As the endian of float and uint32_t may differ. __BYTE_ORDER__ is for integers. __FLOAT_WORD_ORDER__ is for FP. IAC, is is a GNU extension and not certainly available with other compilers. Aug 1 at 16:45
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    @MaximEgorushkin "what platform are byte orders of float and uint32_t different" is a good question to post. I have not, in last 10 yrs seen such and wonder too how common it remains - it certainly is rare. number of hardware architectures where floating-point numbers are represented in big-endian form while integers are represented in little-endian form. IAC, C does not require the same endian. What specifically is the bug you are suggesting in ieee754.h? That already supports different endian for integer/float. Aug 2 at 14:03

1 Answer 1


Is checking the location of the sign bit enough to determine endianness of IEEE-754 float with respect to integer endianness?

  • As I read it, given the C++ spec and the C spec that it tends to also rely on, checking the sign bit is technically insufficient to determine endian relationship between float/uint32_t. It is likely practically sufficient as endians other than big/little are rare as well as differences between float/uint32_t endian.

  • I would suggest a different constant than -0.0f, maybe -0x1.ca8642p-113f which has the pattern 0x87654321 and would be a more thorough endian test. Quite unclear why OP wants to use a one's-bit-sparse -0.0f to discern 3 possible results.

  • As mentioned by others, in C++, the test should be a compile time one, so thoroughness is not a run-time cost over the simplicity of only testing a sign bit.

  • Relying on is_iec559 is true may unnecessarily limits portability as for that to be true, many non-finite compliance rules are needed. ref. Does your code really need quiet and signaling NANs?

  • See also If is_iec559 is true, does that mean that I can extract exponent and mantissa in a well defined way?.

  • I hope OP also tests that the sizeof(float) == sizeof(uint32_t) else memcpy(&view, &check, sizeof(check)) is bad code.

is my approach a robust and portable way of making sure I get the floats "the right way round" when I chop them up?

  • Code is not as robust and portable as it could be.

  • "when I chop them up" --> that code is not shown, so unanswerable. I am suspect of the endianness() goal that is used to support "uses memcpy to unpack float/double to unsigned integers of the appropriate width, and then uses some bit-shifting to separate the sign bit from the combined significand/exponent." It is that code that deserves review.

  • For the purposes of what I'm doing (a little bit of bit-hacking on IEEE-754's representation), I'm completely ok with requiring is_iec559() if it means I can guarantee (up to the point of a lying implementation of std::numeric_limits ;) ) that my floats are indeed IEEE-754. I only care that my code is portable among all systems that use IEEE-754 format.
    – saxbophone
    Aug 1 at 17:34
  • @saxbophone 1) Since "only care that my code is portable" is the issue, not "Is checking the location of the sign bit enough", that code should be reviewed. 2) Requiring is_iec559() limits portability. Aug 1 at 17:39
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    @saxbophone Yes, codereview is a goods place for code review, given that you reasonable believe it is error free. Aug 1 at 17:48
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    @saxbophone Yes, that what a more robust pattern than 0x80000000 provides. IMO, consider the 3 known integer endians (big, little, PDP) and 2 known FP endians (big, little) (e.g. GCC __BYTE_ORDER__, __FLOAT_WORD_ORDER__ and what those combinations could result in your test. Yet I still think this dances around the issue as it is the unposted float-chopping code itself that deserves review. Possible a good solution for that may not even need endianness(). Aug 1 at 18:02
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    That is a really good point about the potential lack of need for the approach I'm using in the first place. I think my question might have hit the XY problem. Thank you for your forensic answer and follow-up, it is most helpful.
    – saxbophone
    Aug 1 at 18:07

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