Little vs Big Endianess: How to interpret the test

So I'm writing a program to test the endianess of a machine and print it. I understand the difference between little and big endian, however, from what I've found online, I don't understand why these tests show the endianess of a machine.

This is what I've found online. What does *(char *)&x mean and how does it equaling one prove that a machine is Little-Endian?

``````int x = 1;
if (*(char *)&x == 1) {
printf("Little-Endian\n");
} else {
printf("Big-Endian\n");
}
``````
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If you "already understand" the difference between big and little endian, why then is a basic test of endianess not understandable? –  wallyk Apr 2 '12 at 5:42
I know what it does and am not entirely sure why checking if a dereferenced version of the variable, cast as a pointer to a char will tell you that. Unless the endianness of a char is standard, in which case it'll tell you if it changes during that bitwise-cast. –  zebediah49 Apr 2 '12 at 5:46

If we split into different parts:

1. `&x`: This gets the address of the location where the variable `x` is, i.e. `&x` is a pointer to `x`. The type is `int *`.

2. `(char *)&x`: This takes the address of `x` (which is a `int *`) and converts it to a `char *`.

3. `*(char *)&x`: This dereferences the `char *` pointed to by `&x`, i.e. gets the values stored in `x`.

Now if we go back to `x` and how the data is stored. On most machines, `x` is four bytes. Storing `1` in `x` sets the least significant bit to `1` and the rest to `0`. On a little-endian machine this is stored in memory as `0x01 0x00 0x00 0x00`, while on a big-endian machine it's stored as `0x00 0x00 0x00 0x01`.

What the expression does is get the first of those bytes and check if it's `1` or not.

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Here's what the memory will look like, assuming a 32b integer:

``````Little-endian
0x01000000 = 00000001000...00

Big-endian
0x00000001 = 0......01
``````

Dereferencing a `char *` gives you one byte. Your test fetches the first byte at that memory location by interpreting the address as a `char *` and then dereferencing it.

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`0x80000000` typo? –  Hunter McMillen Apr 2 '12 at 5:46
@HunterMcMillen Could be. What do you mean ? –  cnicutar Apr 2 '12 at 5:48
Maybe I am confused, are you using `0x80000000` as the byte address in memory? –  Hunter McMillen Apr 2 '12 at 5:49
@HunterMcMillen I'm using it to represent the number `2^31` in base 16. –  cnicutar Apr 2 '12 at 5:49
I was confused, my mistake. –  Hunter McMillen Apr 2 '12 at 5:51

Breaking down `*(char *)&x`:

`&x` is the address of integer x

`(char *)` causes address of integer x to be treated as an address of a character (aka byte)

`*` references the value of the byte

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Obviously @Joahcim Pileborg explained it better and quicker. –  Brian Swift Apr 2 '12 at 5:57
``````int x;
``````

`x` is a variable which can hold a 32-bit value.

``````int x = 1;
``````

A given hardware can store the value `1` as a `32-bit` value in one of the following format.

``````Little Endian
0x100    0x101    0x102    0x103
00000001 00000000 00000000 00000000

(or)

Big Endian
0x100    0x101    0x102    0x103
00000000 00000000 00000000 00000001
``````

Now lets try to break the expression:

``````&x
``````

Get the address of variable `x`. Say the address of `x` is `0x100`.

``````(char *)&x
``````

`&x` is an address of an integer variable. `(char *)&x` converts the address `0x100` from `(int *)` to `(char *)`.

``````*(char *)&x
``````

de-references the value stored in the `(char *)` which is nothing but the first byte (from left to right) in the 4-byte (32-bit integer `x`).

``````(*(char *)&x == 1)
``````

If the first byte from left to right stores the value `00000001`, then it is little endian. If the 4th byte from left to right stores value `00000001`, then it is big endian.

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thank you! I have another quick question, if you don't mind. Will (char *)&x give me a string of the address of x? Also, how can I get the value of all individual bits in a variable? An entire byte per say. –  alexthebake Apr 2 '12 at 6:30
A loose definition of a C-string is - "one or more (array of) characters (char) which are terminated by '\0'". In C, a string can be represented as `char x[]` or `char *x`. –  Sangeeth Saravanaraj Apr 2 '12 at 6:50
For bit operations, please refer catonmat.net/blog/low-level-bit-hacks-you-absolutely-must-know –  Sangeeth Saravanaraj Apr 2 '12 at 6:52

``````#include <iostream>
#include <cstdlib>
#include <cmath>

using namespace std;

int main()
{
cout<<"sizeof(char) = "<<sizeof(char)<<endl;
cout<<"sizeof(unsigned int) = "<<sizeof(unsigned int)<<endl;
//NOTE: Windows, Mac OS, and Linux and Tru64 Unix are Little Endian architectures
//Little Endian means the memory value increases as the digit significance increases
//Proof for Windows:

unsigned int x = 0x01020408; //each hexadecimal digit is 4 bits, meaning there are 2
//digits for every byte
char *c = (char *)&x;
unsigned int y = *c*pow(16,0) +pow(16,2) * *(c+1)+pow(16,4) * *(c+2)+pow(16,6) * *(c+3);
//Here's the test: construct the sum y such that we select subsequent bytes of 0x01020408
//in increasing order and then we multiply each by its corresponding significance in
//increasing order.  The convention for hexadecimal number definitions is that
//the least significant digit is at the right of the number.
//Finally, if (y==x),then...
if (y==x) cout<<"Little Endian"<<endl;
else cout<<"Big Endian"<<endl;

cout<<(int) *c<<endl;
cout<<(int) *(c+1)<<endl;
cout<<(int) *(c+2)<<endl;
cout<<(int) *(c+3)<<endl;
cout<<"x is "<<x<<endl;
cout<<(int)*c<<"*1 + "<<(int)*(c+1)<<"*16^2 + "<<(int)*(c+2)<<"*16^4 + "<<(int)*(c+3)<<" *16^6 = "<<y<<endl;
system("PAUSE"); //Only include this on a counsel program
return 0;
}
``````

This displays 8 4 2 1 for the dereferenced values at c, c+1, c+2, and c+3 respectively. The sum y is 16909320, which is equal to x. Even though the significance of the digits grow from right-to-left, this is still Little Endian because the corresponding memory values also grow from right-to-left, which is why the left-shift binary operator << would increase a variable's value until non-zero digits are shifted off the variable altogether. Don't confuse this operator with std::cout's << operator. If this were Big Endian, then the display for c, c+1, c+2, and c+3 respectively would look like: 1 2 4 8

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