# How to create mask with least significat bits set to 1 in C

Can someone please explain this function to me?

A mask with the least significant n bits set to 1.

Ex:

n = 6 --> 0x2F, n = 17 --> 0x1FFFF // I don't get these at all, especially how n = 6 --> 0x2F

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also what is a mask? How about Wikipedia? –  chris Sep 14 '12 at 0:34
The 0x2F is wrong by the way, it should be 0x3f –  wich Sep 14 '12 at 0:36
@chris wiki is too confusion... –  sebi Sep 14 '12 at 0:39

The usual way is to take a `1`, and shift it left `n` bits. That will give you something like: `00100000`. Then subtract one from that, which will clear the bit that's set, and set all the less significant bits, so in this case we'd get: `00011111`.

A mask is normally used with bitwise operations, especially `and`. You'd use the mask above to get the 5 least significant bits by themselves, isolated from anything else that might be present. This is especially common when dealing with hardware that will often have a single hardware register containing bits representing a number of entirely separate, unrelated quantities and/or flags.

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Keep in mind that going `1 << w - 1`, where `w` is the width of the data type, to set all but one of the bits, is UB. –  chris Sep 14 '12 at 0:37
Exactly. Blame it on Intel, but it made it to the standard. –  wildplasser Sep 14 '12 at 0:38

I believe your first example should be `0x3f`.

`0x3f` is hexadecimal notation for the number `63` which is `111111` in binary, so that last 6 bits (the least significant 6 bits) are set to `1`.

The following little C program will calculate the correct mask:

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

{

for (int i = 0; i < n; ++i)

}

int main (int argc, char const *argv[])
{
return 0;
}
``````
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`0x2F` is `0010 1111` in binary - this should be `0x3f`, which is `0011 1111` in binary and which has the 6 least-significant bits set.

Similarly, `0x1FFFF` is `0001 1111 1111 1111 1111` in binary, which has the 17 least-significant bits set.

A "mask" is a value that is intended to be combined with another value using a bitwise operator like `&`, `|` or `^` to individually set, unset, flip or leave unchanged the bits in that other value.

For example, if you combine the mask `0x2F` with some value `n` using the `&` operator, the result will have zeroes in all but the 6 least significant bits, and those 6 bits will be copied unchanged from the value `n`.

In the case of an `&` mask, a binary `0` in the mask means "unconditionally set the result bit to 0" and a `1` means "set the result bit to the input value bit". For an `|` mask, an `0` in the mask sets the result bit to the input bit and a `1` unconditionally sets the result bit to `1`, and for an `^` mask, an `0` sets the result bit to the input bit and a `1` sets the result bit to the complement of the input bit.

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Ops. Got the wrong edit after your update, but I did rollback. Sorry! –  jweyrich Sep 14 '12 at 0:44

A mask is a common term for an integer value that is bit-wise ANDed, ORed, XORed, etc with another integer value.

For example, if you want to extract the 8 least significant digits of an int variable, you do `variable & 0xFF`. 0xFF is a mask.

Likewise if you want to set bits 0 and 8, you do `variable | 0x101`, where 0x101 is a mask.

Or if you want to invert the same bits, you do `variable ^ 0x101`, where 0x101 is a mask.

To generate a mask for your case you should exploit the simple mathematical fact that if you add 1 to your mask (the mask having all its least significant bits set to 1 and the rest to 0), you get a value that is a power of 2.

So, if you generate the closest power of 2, then you can subtract 1 from it to get the mask.

Positive powers of 2 are easily generated with the left shift `<<` operator in C.

Hence, `1 << n` yields 2n. In binary it's 10...0 with `n` 0s.

`(1 << n) - 1` will produce a mask with `n` lowest bits set to 1.

Now, you need to watch out for overflows in left shifts. In C (and in C++) you can't legally shift a variable left by as many bit positions as the variable has, so if ints are 32-bit, `1<<32` results in `undefined behavior`. Signed integer overflows should also be avoided, so you should use unsigned values, e.g. `1u << 31`.

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