I thought of using tests at runtime to determine the endianness so that I can be sure of the behaviour of shifts, and noticed a somewhat peculiar optimization by my compiler. It would suggest that the endianness of the machine it will run on is known at compile time.

These are the two routines I timed. Routine 2, which makes use of const, was about 33% faster.

```
/* routine 1 */
int big_endian = 1 << 1;
for (register int i = 0; i < 1000000000; ++i) {
int value = big_endian ? 5 << 2 : 5 >> 2;
value = ~value;
}
/* routine 2 */
const int big_endian = 1 << 1;
for (register int i = 0; i < 1000000000; ++i) {
int value = big_endian ? 5 << 2 : 5 >> 2;
value = ~value;
}
```

The speed of routine 2 matches that of using a constant expression computable at compile time. How is this possible, if the behaviour of shifts depends on the processor?

Also, on a side note, why do we call numbers that end with the *least* significant digit *big* endian numbers, and those that end with the *most* significant digit *little* endian numbers.

**Edit:**

Some people in the comments claim bitwise shifts have nothing to do with endianness. If this is true, does that mean that a number such as 3 is always stored as `00000011 (big endian)`

and never as `11000000 (little endian)?`

And if this is indeed the case, which actually does seem to make sense, wouldn't it act weird when using little endian, since `10000000 00000000 00000000 (128)`

shifted to the left by one would become `00000000 00000001 00000000 (256)?`

Thank you in advance.

`big_endian`

willalwaysbe 2, no matter what the endianness of the target system is. – Rob Kennedy Aug 21 '12 at 17:48startwith the least-significant digit. – Keith Randall Aug 21 '12 at 17:49