I am using the HIDAPI to send some data to a USB device. This data can be sent only as byte array and I need to send some float numbers inside this data array. I know floats have 4 bytes. So I thought this might work:

float f = 0.6;
char data[4];

data[0] = (int) f >> 24;
data[1] = (int) f >> 16;
data[2] = (int) f >> 8;
data[3] = (int) f;

And later all I had to do is:

g = (float)((data[0] << 24) | (data[1] << 16) | (data[2] << 8) | (data[3]) );

But testing this shows me that the lines like data[0] = (int) f >> 24; returns always 0. What is wrong with my code and how may I do this correctly (i.e. break a float inner data in 4 char bytes and rebuild the same float later)?


I was able to accomplish this with the following codes:

float f = 0.1;
unsigned char *pc;
pc = (unsigned char*)&f;

// 0.6 in float
pc[0] = 0x9A;
pc[1] = 0x99;
pc[2] = 0x19;
pc[3] = 0x3F;

std::cout << f << std::endl; // will print 0.6


*(unsigned int*)&f = (0x3F << 24) | (0x19 << 16) | (0x99 << 8) | (0x9A << 0);

I know memcpy() is a "cleaner" way of doing it, but this way I think the performance is somewhat better.

  • 1
    The reason (int)f >> 24 returns 0 is that the int casted f is equal to 0 in the first place: the cast sends the float to its floor. It's undefined behavior but to do it that hacky way you would need something like *(int*)&f >> 24. – Andrey Mishchenko Jan 8 '14 at 20:46

You can do it like this:

char data[sizeof(float)];

float f = 0.6f;

memcpy(data, &f, sizeof f);    // send data

float g;

memcpy(&g, data, sizeof g);    // receive data

In order for this to work, both machines need to use the same floating point representations.

As was rightly pointed out in the comments, you don't necessarily need to do the extra memcpy; instead, you can treat f directly as an array of characters (of any signedness). You still have to do memcpy on the receiving side, though, since you may not treat an arbitrary array of characters as a float! Example:

unsigned char const * const p = (unsigned char const *)&f;
for (size_t i = 0; i != sizeof f; ++i)
    printf("Byte %zu is %02X\n", i, p[i]);
  • silly question, why the 'f' after 0.6? I have seen it before, just never saw the reason... – Michel Feinstein Jan 8 '14 at 20:49
  • I like this answer, but I got curious, there arent any other ways for doing a byte level acess on a float? – Michel Feinstein Jan 8 '14 at 20:54
  • 1
    @mFeinstein 0.6f is a constant of type float, 0.6 is a constant of type double. A constant of type double would be converted to float automatically anyway (but naive compilers might generate worse code for f = 0.6, and some platforms might round differently). There are other ways of doing byte-level access, but memcpy is the best way here. – Gilles 'SO- stop being evil' Jan 8 '14 at 21:19
  • @Gilles: Yes, you can treat f directly as an array of chars: char const * data = (char const *)&f;, now use data[i] for a range of i. – Kerrek SB Jan 8 '14 at 21:20
  • There are places where failing to distinguish between float, double, and int constants may get you in trouble, so it isn't a bad idea to make a habit of always specifying the f or d suffix. Having said that, I must admit I tend to do so only when I either need to make sure it's the right type or need to make sure the reader understands what type it is. – keshlam Jan 8 '14 at 21:21

In standard C is guaranted that any type can be accessed as an array of bytes. A straight way to do this is, of course, by using unions:

 #include <stdio.h> 

 int main(void)
    float x = 0x1.0p-3; /* 2^(-3) in hexa */

    union float_bytes {
       float val;
       unsigned char bytes[sizeof(float)];
    } data;

    data.val = x;
    for (int i = 0; i < sizeof(float); i++) 
          printf("Byte %d: %.2x\n", i, data.bytes[i]);

    data.val *= 2;   /* Doing something with the float value */
    x = data.val;    /* Retrieving the float value           */
    printf("%.4f\n", data.val);


As you can see, it is not necessary at all to use memcpy or pointers...

The union approach is easy to understand, standard and fast.


I will explain why this approach is valid in C (C99).

  • [] A byte has CHAR_BIT bits (an integer constant >= 8, in almost cases is 8).
  • [] The unsigned char type uses all its bits to represent the value of the object, which is an nonnegative integer, in a pure binary representation. This means that there are not padding bits or bits used for any other extrange purpouse. (The same thing is not guaranted for signed char or char types).
  • [] Every non-bitfield type is represented in memory as a contiguous sequence of bytes.
  • [] (Cited) "Values stored in non-bit-field objects of any other object type consist of n × CHAR_BIT bits, where n is the size of an object of that type, in bytes. The value may be copied into an object of type unsigned char [n] (e.g., by memcpy); [...]"
  • [] A pointer to a structure object (in particular, unions), suitably converted, points to its initial member. (Thus, there is no padding bytes at the beginning of a union).
  • [6.5(7)] The content of an object can be accessed by a character type:

An object shall have its stored value accessed only by an lvalue expression that has one of the following types:
— a type compatible with the effective type of the object,
— a qualified version of a type compatible with the effective type of the object,
— a type that is the signed or unsigned type corresponding to the effective type of the object,
— a type that is the signed or unsigned type corresponding to a qualified version of the effective type of the object,
— an aggregate or union type that includes one of the aforementioned types among its members (including, recursively,amember of a subaggregate or contained union), or
a character type

More information:

A discussion in google groups


Another detail of the standard C99:

  • [ footnote 82] Type-punning is allowed:

If the member used to access the contents of a union object is not the same as the member last used to store a value in the object, the appropriate part of the object representation of the value is reinterpreted as an object representation in the new type as described in 6.2.6 (a process sometimes called "type punning"). This might be a trap representation.

  • 3
    I'd like to note that while this may be valid in C (C99, I think, but not C89?), this would be undefined behaviour in C++. Just in case any C++ users walk by and see this. – Kerrek SB Jan 8 '14 at 22:42
  • @KerrekSB : Yes, my code is standard in C99. I am not pretty sure if the union technique is standard in C89. (The int inside the for loop is valid only in C99). However, the question has the tag c but not c++. – pablo1977 Jan 8 '14 at 22:53
  • Yes, of course, it was just a remark. Sometimes people think they can apply things from one language to the other, so I just wanted to be on the safe side. C is a lot more relaxed about accessing memory than C++ is; I don't have the standard reference that says this is valid, but I trust you're right. – Kerrek SB Jan 8 '14 at 23:03
  • 1
    @KerrekSB I walked into the type-punning through unions mine field in this answer and I linked some of the better discussions on this. Pascal Cuoq's interpretation and the DR he links supports that it has been legal since C89. The C++ case is not clear at all and I would lean on the side of it being undefined but it may not be. – Shafik Yaghmour Jan 9 '14 at 4:13
  • 1
    @KerrekSB I was referring to Purpose of Unions in C and C++ and also I linked this one Accessing inactive union member - undefined?. – Shafik Yaghmour Jan 9 '14 at 10:25

The C language guarantees that any value of any type¹ can be accessed as an array of bytes. The type of bytes is unsigned char. Here's a low-level way of copying a float to an array of bytes. sizeof(f) is the number of bytes used to store the value of the variable f; you can also use sizeof(float) (you can either pass sizeof a variable or more complex expression, or its type).

float f = 0.6;
unsigned char data[sizeof(float)];
size_t i;
for (i = 0; i < sizeof(float); i++) {
    data[i] = (unsigned char*)f + i;

The functions memcpy or memmove do exactly that (or an optimized version thereof).

float f = 0.6;
unsigned char data[sizeof(float)];
memcpy(data, f, sizeof(f));

You don't even need to make this copy, though. You can directly pass a pointer to the float to your write-to-USB function, and tell it how many bytes to copy (sizeof(f)). You'll need an explicit cast if the function takes a pointer argument other than void*.

int write_to_usb(unsigned char *ptr, size_t size);
result = write_to_usb((unsigned char*)f, sizeof(f))

Note that this will work only if the device uses the same representation of floating point numbers, which is common but not universal. Most machines use the IEEE floating point formats, but you may need to switch endianness.

As for what is wrong with your attempt: the >> operator operates on integers. In the expression (int) f >> 24, f is cast to an int; if you'd written f >> 24 without the cast, f would still be automatically converted to an int. Converting a floating point value to an integer approximates it by truncating or rounding it (usually towards 0, but the rule depends on the platform). 0.6 rounded to an integer is 0 or 1, so data[0] is 0 or 1 and the others are all 0.

You need to act on the bytes of the float object, not on its value.

¹ Excluding functions which can't really be manipulated in C, but including function pointers which functions decay to automatically.

  • Is to possible to do in one line, without the for? using << and | to split the bytes? – Michel Feinstein Jan 8 '14 at 21:40
  • @mFeinstein << and other integer operations won't help you there. See my edit. – Gilles 'SO- stop being evil' Jan 8 '14 at 21:47
  • Yes I see, but I thought casting the float to a unsigned char array might do the trick. I am just trying to avoiding unnecessary code since this will run in a interrupt. But if it starts to complicate so memcpy will be almost the same and I will use it. – Michel Feinstein Jan 8 '14 at 22:05
  • @mFeinstein You can't cast to an array type, but casting a pointer to the float to an unsigned char * does essentially the same thing. – Gilles 'SO- stop being evil' Jan 8 '14 at 22:10

Assuming that both devices have the same notion of how floats are represented then why not just do a memcpy. i.e

unsigned char payload[4];
memcpy(payload, &f, 4);
  • Because the bytes will be read back in a microcontroller and I wasnt sure there was a memcpy in the microcontroller librabry....but now I see there is – Michel Feinstein Jan 8 '14 at 21:08

the safest way to do this, if you control both sides is to send some sort of standardized representation... this isn't the most efficient, but it isn't too bad for small numbers.

hostPort writes char * "34.56\0" byte by byte
client reads char * "34.56\0" 

then converts to float with library function atof or atof_l.

of course that isn't the most optimized, but it sure will be easy to debug.

if you wanted to get more optimized and creative, first byte is length then the exponent, then each byte represents 2 decimal places... so

34.56 becomes char array[] = {4,-2,34,56}; something like that would be portable... I would just try not to pass binary float representations around... because it can get messy fast.

  • This will be a lot cumbersome for my needs since I have a microcontroller to receive the data and the performance is not the best one around – Michel Feinstein Jan 8 '14 at 20:51

It might be safer to union the float and char array. Put in the float member, pull out the 4 (or whatever the length is) bytes.

  • Actually, no, abusing a union this way is not safe. If you write to a member of a union, you're not allowed to read back from another member (it's undefined behavior). Compilers take advantage of this restriction to optimize. – Gilles 'SO- stop being evil' Jan 8 '14 at 21:17
  • Bull. That's the whole purpose of a union... to put in data in one format and pull out the unaltered bits as another format. – Phil Perry Jan 9 '14 at 14:28
  • 1
    No, this is not the purpose of a union. The purpose of a union is to use the same slice of memory to store different data as different times. In C89, the behavior is implementation-defined. In C++, GCC does take advantage of this to optimize; I thought some versions also did this in C, but after looking it up I was wrong: this is safe with GCC. C11 has also changed to make this defined, so it's probably safe in practice on current compilers, even if they aren't fully C11 compliant. – Gilles 'SO- stop being evil' Jan 9 '14 at 15:42
  • 1
    Again, no, you have it exactly backwards. Type punning in unions was explicitly not standard (though widely supported) in earlier versions of the standard. The primary purpose of a union is to store different, unrelated objects in the same space in memory (often, but not necessarily, with an enum or integer object nearby indicating which field of the union is currently valid). – Gilles 'SO- stop being evil' Jan 9 '14 at 17:45
  • 1
    @Gilles The footnote in the answer stackoverflow.com/questions/11373203/… that you link to was already there in C99TC3. If you believe in standard committee infallibility, this means that it was in the C99 standard all along, although not expressed explicitly. Under this interpretation, none of C89, C99 and C11 make it undefined to use a union for type-punning. – Pascal Cuoq Jan 9 '14 at 23:17

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