How to get the value of individual bytes of a variable?

I know that to get the number of bytes used by a variable type, you use `sizeof(int)` for instance. How do you get the value of the individual bytes used when you store a number with that variable type? (i.e. `int x = 125`.)

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You can get the bytes by using some pointer arithmetic:

``````int x = 12578329; // 0xBFEE19
for (size_t i = 0; i < sizeof(x); ++i) {
// Convert to unsigned char* because a char is 1 byte in size.
// That is guaranteed by the standard.
// Note that is it NOT required to be 8 bits in size.
unsigned char byte = *((unsigned char *)&x + i);
printf("Byte %d = %u\n", i, (unsigned)byte);
}
``````

On my machine (Intel x86-64), the output is:

``````Byte 0 = 25  // 0x19
Byte 1 = 238 // 0xEE
Byte 2 = 191 // 0xBF
Byte 3 = 0 // 0x00
``````
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How 4294967278 is a byte? Default `char` type is probably signed on your system and casting into `unsigned` produces large numbers. –  Eser Aygün Dec 30 '11 at 14:15
@Eser Aygün I'll update the code. Thanks for the comment. –  user142019 Dec 30 '11 at 14:17
Any reason to use manual pointer arithmetic instead of the much more readable array access? –  Konrad Rudolph Dec 30 '11 at 14:19
@Konrad Rudolph because it was the first thing I came up with. –  user142019 Dec 30 '11 at 14:20
what happens if u use 'char' instead of 'unsigned char' –  toby Dec 30 '11 at 14:38

You have to know the number of bits (often 8) in each "byte". Then you can extract each byte in turn by ANDing the int with the appropriate mask. Imagine that an int is 32 bits, then to get 4 bytes out of the_int:

``````  int a = (the_int >> 24) & 0xff;  // high-order (leftmost) byte: bits 24-31
int b = (the_int >> 16) & 0xff;  // next byte, counting from left: bits 16-23
int c = (the_int >>  8) & 0xff;  // next byte, bits 8-15
int d = the_int         & 0xff;  // low-order byte: bits 0-7
``````

And there you have it: each byte is in the low-order 8 bits of a, b, c, and d.

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+1: I consider this far better than fiddling with memory location. 1) if is endian-agnostic. 2) The CPU can perform operations in processor registers, so it is typically far more efficient. In fact, for some (8-bit) machines, this might not generate any code at all (if you have a decent compiler). –  Lindydancer Dec 30 '11 at 14:40
It would be a better example if the type of `a`, `b` etc. would have been `unsigned char`. In that case, the compiler could allocate the variables in the same processor registers that holds `the_int`, if they are of the right size. –  Lindydancer Dec 30 '11 at 14:53
+1 this answer is the most correct. All the others are endian dependent. @dip it's not processor intensive on many platforms, and anyway, the compiler will transform this into whatever is the best implementation behind the scenes. –  ams Dec 30 '11 at 14:59
@PeteWilson: I would say that the case where a `char` isn't 8 bits is so rare that you would have to hand-craft everything anyway. I guess that one could write the code using the `CHAR_BITS` macro to be on the safe side, but I don't think it's worth the effort. Thanks for your offer -- I do dance the Lindy Hop and I do (normally) remain upright (even though I don't do aerials), however I would prefer it if you would upvote my answers based on the content rather than on my performance on the dance floor ;) –  Lindydancer Dec 30 '11 at 15:27
@ams so I see, something new learned and for Pete What I meant is that lot of CPU's shifts are done per bits and cost more cycles (just like multiplying, dividing, modulo and branching) than simple bit manipulations and read / writes etc. But you're right, it is the best way to do this I know now. Sorry for being a pain =) –  DipSwitch Dec 30 '11 at 16:13

If you want to get that information, say for:

``````int value = -278;
``````

(I selected that value because it isn't very interesting for 125 - the least significant byte is 125 and the other bytes are all 0!)

You first need a pointer to that value:

``````int* pointer = &value;
``````

You can now typecast that to a 'char' pointer which is only one byte, and get the individual bytes by indexing.

``````for (int i = 0; i < sizeof(value); i++) {
char thisbyte = *( ((char*) pointer) + i );
// do whatever processing you want.
}
``````

Note that the order of bytes for ints and other data types depends on your system - look up 'big-endian' vs 'little-endian'.

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Any reason to use manual pointer arithmetic instead of the much more readable array access? –  Konrad Rudolph Dec 30 '11 at 14:19
Because it makes it obvious to those being educated that we're using a pointer? I don't consider pointer arithmetic to be wrong or unreadable. –  Dan Dec 30 '11 at 14:21
It’s not wrong but surely you don’t argue that it’s as readable as array access …! Compare `*(x + i)` with `x[i]`. In fact, why does array access syntax exist at all, if we don’t use it when appropriate? –  Konrad Rudolph Dec 30 '11 at 14:21
thanks alot!!!.. –  toby Dec 30 '11 at 14:38

You could make use of a `union` but keep in mind that the byte ordering is processor dependent and is called Endianness http://en.wikipedia.org/wiki/Endianness

``````#include <stdio.h>
#include <stdint.h>

union my_int {
int val;
uint8_t bytes[sizeof(int)];
};

int main(int argc, char** argv) {
union my_int mi;
int idx;

mi.val = 128;

for (idx = 0; idx < sizeof(int); idx++)
printf("byte %d = %hhu\n", idx, mi.bytes[idx]);

return 0;
}
``````
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@WTP ah lol, didn't even notice :p –  DipSwitch Dec 30 '11 at 14:26

This should work:

``````int x = 125;
unsigned char *bytes = (unsigned char *) (&x);
unsigned char byte0 = bytes[0];
unsigned char byte1 = bytes[1];
...
unsigned char byteN = bytes[sizeof(int) - 1];
``````

But be aware that the byte order of integers is platform dependent.

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byte ordering is CPU dependent not OS dependent –  DipSwitch Dec 30 '11 at 14:13
@DipSwitch You're right. Corrected. –  Eser Aygün Dec 30 '11 at 14:19