21

I'm trying to build a 32-bit float out of its 4 composite bytes. Is there a better (or more portable) way to do this than with the following method?

#include <iostream>

typedef unsigned char uchar;

float bytesToFloat(uchar b0, uchar b1, uchar b2, uchar b3)
{
    float output;

    *((uchar*)(&output) + 3) = b0;
    *((uchar*)(&output) + 2) = b1;
    *((uchar*)(&output) + 1) = b2;
    *((uchar*)(&output) + 0) = b3;

    return output;
}

int main()
{
    std::cout << bytesToFloat(0x3e, 0xaa, 0xaa, 0xab) << std::endl; // 1.0 / 3.0
    std::cout << bytesToFloat(0x7f, 0x7f, 0xff, 0xff) << std::endl; // 3.4028234 × 10^38  (max single precision)

    return 0;
}
  • 3
    Considering that this was my first question on Stack Overflow, I'm thrilled at the various responses. I thank everyone for their input. – Madgeek Oct 21 '10 at 23:47
27

You could use a memcpy (Result)

float f;
uchar b[] = {b3, b2, b1, b0};
memcpy(&f, &b, sizeof(f));
return f;

or a union* (Result)

union {
  float f;
  uchar b[4];
} u;
u.b[3] = b0;
u.b[2] = b1;
u.b[1] = b2;
u.b[0] = b3;
return u.f;

But this is no more portable than your code, since there is no guarantee that the platform is little-endian or the float is using IEEE binary32 or even sizeof(float) == 4.

(Note*: As explained by @James, it is technically not allowed in the standard (C++ §[class.union]/1) to access the union member u.f.)

  • 3
    To solve the sizeof(float) problem you may just declare the b member as uchar b[sizeof(float)];. – Matteo Italia Oct 21 '10 at 20:35
  • @Matteo: Right, but then the input needs to be modified as well. – kennytm Oct 21 '10 at 20:40
  • 1
    The union method results in undefined behavior. – xskxzr Jun 29 '18 at 12:26
15

The following functions pack/unpack bytes representing a single precision floating point value to/from a buffer in network byte order. Only the pack method needs to take endianness into account since the unpack method explicitly constructs the 32-bit value from the individual bytes by bit shifting them the appropriate amount and then OR-ing them together. These functions are only valid for C/C++ implementations that store a float in 32-bits. This is true for IEEE 754-1985 floating point implementations.

// unpack method for retrieving data in network byte,
//   big endian, order (MSB first)
// increments index i by the number of bytes unpacked
// usage:
//   int i = 0;
//   float x = unpackFloat(&buffer[i], &i);
//   float y = unpackFloat(&buffer[i], &i);
//   float z = unpackFloat(&buffer[i], &i);
float unpackFloat(const void *buf, int *i) {
    const unsigned char *b = (const unsigned char *)buf;
    uint32_t temp = 0;
    *i += 4;
    temp = ((b[0] << 24) |
            (b[1] << 16) |
            (b[2] <<  8) |
             b[3]);
    return *((float *) &temp);
}

// pack method for storing data in network,
//   big endian, byte order (MSB first)
// returns number of bytes packed
// usage:
//   float x, y, z;
//   int i = 0;
//   i += packFloat(&buffer[i], x);
//   i += packFloat(&buffer[i], y);
//   i += packFloat(&buffer[i], z);
int packFloat(void *buf, float x) {
    unsigned char *b = (unsigned char *)buf;
    unsigned char *p = (unsigned char *) &x;
#if defined (_M_IX86) || (defined (CPU_FAMILY) && (CPU_FAMILY == I80X86))
    b[0] = p[3];
    b[1] = p[2];
    b[2] = p[1];
    b[3] = p[0];
#else
    b[0] = p[0];
    b[1] = p[1];
    b[2] = p[2];
    b[3] = p[3];
#endif
    return 4;
}
  • 1
    I think there is a mistake in the code line: return *((float *) temp); It should be: return *((float *) &temp); – Ami DATA Apr 25 '17 at 8:43
14

You can use std::copy:

float bytesToFloat(uchar b0, uchar b1, uchar b2, uchar b3) 
{ 
    uchar byte_array[] = { b3, b2, b1, b0 };
    float result;
    std::copy(reinterpret_cast<const char*>(&byte_array[0]),
              reinterpret_cast<const char*>(&byte_array[4]),
              reinterpret_cast<char*>(&result));
    return result;
} 

This avoids the union hack, which isn't technically allowed by the language. It also avoids the commonly used reinterpret_cast<float*>(byte_array), which violates the strict aliasing rules (it is permitted to reinterpret any object as an array of char, so the reinterpret_casts in this solution do not violate the strict aliasing rules).

It still relies on float being four bytes in width and relies on your four bytes being a valid floating point number in your implementation's floating point format, but you either have to make those assumptions or you have to write special handling code to do the conversion.

  • This still isn't portable, right? I'm just curious... – JoshD Oct 21 '10 at 20:29
  • @JoshD: No; it still relies on sizeof(float) == 4 and doesn't take endianness into consideration. It just avoids reinterpret_cast<float*>(some_uchar_array) and the union hack. – James McNellis Oct 21 '10 at 20:30
  • I'm fairly certain that reinterpret_cast<float*>(byte_array) must be allowed if the byte_array (1) is aligned properly and (2) actually contains a float. I think so because otherwise it would be impossible to memcpy a float to another float (since memcpy writes to a byte array), and yet a float is the archetypical POD type. – MSalters Oct 22 '10 at 10:55
  • @MSalters: But memcpy doesn't reinterpret a byte array as a float; it reinterprets a float as a byte array. – James McNellis Oct 22 '10 at 15:36
  • It's indeed not memcpy itself; that obviously works only on byte arrays. It's the guarantee that you can use the output byte array as a float. – MSalters Oct 25 '10 at 8:17
4

There's no way to do this portable, since different platforms can use:

  • different byte ordering (big endian vs. little endian)
  • different representations for floating point values (see http://en.wikipedia.org/wiki/IEEE_754-1985 for an example)
  • different sizes for floating point values

I also wonder where you get these 4 bytes from?

If I assume that you get them from another system, and you can guarantee that both systems use exactly the same method to store floating-point values in memory, you can use the union trick. Otherwise, your code is almost guaranteed to be non-portable.

3

If you want a portable way to do this, you'll have to write a bit of code to detect the endianess of the system.

float bytesToFloatA(uchar b0, uchar b1, uchar b2, uchar b3)
{
    float output;

    *((uchar*)(&output) + 3) = b0;
    *((uchar*)(&output) + 2) = b1;
    *((uchar*)(&output) + 1) = b2;
    *((uchar*)(&output) + 0) = b3;

    return output;
}


float bytesToFloatB(uchar b0, uchar b1, uchar b2, uchar b3)
{
    float output;

    *((uchar*)(&output) + 3) = b3;
    *((uchar*)(&output) + 2) = b2;
    *((uchar*)(&output) + 1) = b1;
    *((uchar*)(&output) + 0) = b0;

    return output;
}

float (*correctFunction)(uchar b0, uchar b1, uchar b2, uchar b3) = bytesToFloatA;

if ((*correctFunction)(0x3e, 0xaa, 0xaa, 0xab) != 1.f/3.f) // horrifying, I know
{
  correctFunction = bytesToFloatB;
}
  • 1
    That won't be equal in any endians because 1./3. is a double, not a float. You should use something like 1.0f/3. – kennytm Oct 21 '10 at 20:39

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