# Get mosts significant nibble, regardless of int bit length and endianness

My head is starting to hurt... I've been looking at this way too long.

I'm trying to mask the most significant nibble of an int, regardless of the int bit length and the endianness of the machine. Let's say `x = 8425 = = 0010 0000 1110 1001 = 0x20E9`. I know that to get the least significant nibble, 9, I just need to do something like `x & 0xF` to get back 9. But how about the most significant nibble, 2?

I apologize if my logic from here on out falls apart, my brain is completely fried, but here I go:

My book tells me that the bit length w of the data type int can be computed with `w = sizeof(int)<<3`. If I knew that the machine were big-endian, I could do 0xF << w-4 to have 1111 for the most significant nibble and 0000 for the rest, i.e. `1111 0000 0000 0000`. If I knew that the machine were little-endian, I could do 0xF >> w-8 to have `0000 0000 0000 1111`. Fortunately, this works even though we are told to assume that right shifts are done arithmetically just because 0xF always gives me the first bit of 0000. But this is not a proper solution. We are not allowed to test for endianness and then proceed from there, so what do I do?

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"My book tells me that the bit length w of the data type int can be computed with w = sizeof(int)<<3." — please be aware that the book is wrong. It assumes 8-bit bytes and no padding bits. Neiter is necessarily true. –  n.m. Apr 6 '14 at 6:11
Your question is not specific enough. The most significant nibble of `0x20E9` is only `2` if you are on a system with 16-bit `int`. Otherwise it would be `0`. Also, what do you consider the most significant nibble of a negative int? Please clarify. –  Matt McNabb Apr 6 '14 at 6:16

Bit shifting operators operate at a level of abstraction above endianness. "Left" shifts always shift towards the most significant bit, and "right" shifts always shift towards the least significant bit.

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Oh wow. Maybe they should call them big-shift and little-shift to spare a few years from my life :( –  Jeff Apr 6 '14 at 5:58

You should be able to right shift by the `(number of bits) - 4` regardless of endianness. Since you already know how to compute the number of bits, it should suffice to just subtract 4 and shift by that number, and then (for safety), mask with `0xF`.

See this question for discussion about endianness.

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Q But how about the most significant nibble, 2?

A `(x >> (sizeof(int)*8-4)) & 0xF`

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This solution will only work for an `8-bit` integer, because the number of bits to shift is dependent on the bit length of the integer. –  merlin2011 Apr 6 '14 at 5:59
@merlin2011 thanks for noticing the error. It's fixed now. –  R Sahu Apr 6 '14 at 6:03