# 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
For a way to uniformly recover from the UB in this method, see my answer below. –  Joel Snyder Jun 29 at 19:42

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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For both correctness and performance, the best way to accomplish this has changed since this question was asked back in 2012 due to the advent of BMI instructions in modern x86 processors, specifically BLSMSK.

Here's a good way of approaching this problem, while retaining backwards compatibility with older processors.

This method is correct, whereas the current top answers produce undefined behavior in edge cases.

Clang and GCC, when allowed to optimize using BMI instructions, will condense gen_mask() to just two ops. With supporting hardware, be sure to add compiler flags for BMI instructions: `-mbmi -mbmi2`

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

const uint64_t src = (uint64_t)1  << msb;
return (src - 1) ^ src;
}

int main() {
uint_fast8_t msb;
for (msb = 0; msb < 64; ++msb) {
}
return 0;
}
``````
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You have an off-by-one error, AFAICT. –  Ulrich Eckhardt Jun 29 at 19:50
@UlrichEckhardt Actually, I don't see the off-by-one error... it uses the modular arithmetic property of unsigned integers when subtracting (if that's where you think the off-by-one error is). –  Joel Snyder Jun 29 at 19:56
Sorry, that's a misunderstanding: I would have used the width as parameter (like the N that the OP mentioned), but since you use the index of the MSB it's actually consistent. –  Ulrich Eckhardt Jun 29 at 19:59
What does the consting do in this case? –  Arran Cudbard-Bell Aug 27 at 3:40
@ArranCudbard-Bell Consting is for enforcing a promise to the compiler that you'll keep usage of that variable to read-only. It's completely optional: I use it out of habit when prototyping with bit-twiddling micro-optimizations since I've been bitten by bugs in the past that are easily caught by const variables. –  Joel Snyder Aug 27 at 7:32

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