I've got a float variable that I need to send through a CAN protocol. To do so, this float of 32 bits must be cut in 4 uint8_t variables.

I have absolutely no idea of how to do. I was first thinking of convert the float to an int but some answers that I found on the Internet which use cast or union doesn't seems to work.

Here's a simple example of what I'm trying to do :

float f;
uint8_t ut1,ut2,ut3,ut4;

//8 first bits of f into ut1
//8 second bits of f in ut2
...

// Then I can send the uint8_t through CAN
...

Thanks.

up vote 7 down vote accepted

You normally do this by casting the float to an array of uint8_t.

In C you can do it like this:

uint8_t *array;
array = (unit8_t*)(&f);

in C++ use the reinterpret_cast

uint8_t *array;
array = reinterpret_cast<uint8_t*>(&f);

Then array[0], ..., array[3] are your bytes.

  • 1
    How about endianess ? – Jarod42 Aug 19 '14 at 14:57
  • 1
    There may be endianess issues, but that is true however we split the float into bytes. I'd say that is a separate issue. Whatever the protocol specifies the OP will need to adhere to. – dohashi Aug 19 '14 at 15:04

First you should note that the standard imposes no specific size restrictions on float. It's possible that a float wouldn't fit into four bytes on some imaginable architecture (although I'm not aware of any). You should at least (static_)assert that it will fit before attempting anything.

Then I think the simplest way is to assert that CHAR_BIT is 8, and use the legal aliasing to unsigned char* with reinterpret_cast:

static_assert(sizeof(float) == 4);
float f = 0; // whatever value
unsigned char* float_as_char = reinterpret_cast<unsigned char*>(&f);

This totally ignores the endian issue though, so maybe what you really want is to make a copy of the bytes so you can fix that up:

static_assert(sizeof(float) == 4);
float f = 0; // whatever value
uint8_t bytes[4];
std::memcpy(bytes, &f);
// Fix up the order of the bytes in "bytes" now.

You can do this illegal operation:

float f = someFloatValue;
uint8_t* i = reinterpret_cast<uint8_t*>(&f);

Although this works most of the time, it is not supported by c++ standard and compilers might generate code with undefined behaviour.

Another solution is using unions:

union{
    float f;
    uint8_t i[4];
}
f = someFloatValue;
// now i's contain the bit pattern of f

It's unclear if all compilers yield consistent results, but it seems safer than the first aproach.

You can also pack the value of f in a 32-bit integer. This, however can result in losing a bit of precision, but depending on how accurately you want to keep f, would be the best solution.

  • I posted a union answer just before you, but then I realized that it's undefined behaviour: stackoverflow.com/questions/17273320/… – user2079303 Aug 19 '14 at 15:04
  • 1
    Technically, reading from a different union field than the last written to is undefined behavior. However, all major C++ compilers give special guarantees that this will work correctly. This is still the correct answer as there actually is no standard conforming way to achieve this otherwise. – ComicSansMS Aug 19 '14 at 15:06
  • @ComicSansMS Ah, thanks for restoring my faith in the union. – user2079303 Aug 19 '14 at 15:08

Here's a union approach that gives separate names for integer parts instead of one array:

union {
    float f;
    struct {
        uint8_t ut1, ut2, ut3, ut4;
    } bytes;
} value;
value.f = 1.f;
uint8_t first = value.bytes.ut1;

I was initially concerned that this use of union is not strictly legal according to the standard: C++ Undefined behaviour with unions but ComicSansMS's argument in a comment to rashmatash's answer is compelling.

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