23

What is the best way to construct a bit mask in C with m set bits preceded by k unset bits, and followed by n unset bits:

00..0 11..1 00..0
  k     m     n

For example, k=1, m=4, n=3 would result in the bit mask:

01111000
4
  • 1
    For answers to many bit twiddling hacks, such as this, a very good online source is Bit Twiddling Hacks. – Jonathan Leffler Dec 29 '13 at 18:55
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    Customarily, a bitmask macros are defined on inclusive bit indices, something like #define BITS(p,q) ... where p = m + n - 1 and q = n, p >= q – user246672 Oct 8 '15 at 2:39
  • Hacker's Delight is far more comprehensive (1.8 kilopages) and awesome. – user246672 Oct 8 '15 at 2:40
  • @grigy I don't really understand why you need to have k in here. It's just easier to specify a range of bits to set using m and n only. – Nubcake Aug 7 '17 at 23:23
42

~(~0 << m) << n

8
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    This is slick. However, It would be a good idea to comment this line, for the -next- programmer to work on it. – mkClark Nov 25 '08 at 23:41
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    If this was coded as a function (the set_mask_n functions in @quinmar's answer), there'd be a one-line comment saying what the function does (and no argument 'k'), and users of the function would have the name as documentation. As a random expression in a bit of code, it would indubitably be BAD! – Jonathan Leffler Nov 27 '08 at 5:55
  • And, I would hasten (very slowly) to add, my solution would be equally inscrutable if it appeared as an uncommented expression in a bit of code. – Jonathan Leffler Dec 10 '08 at 1:56
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    The ~(~0 << m) is in paragraph 2.9 "Bitwise Operators" of "The C Programming Language, second edition" by Brian Kernighan and Dennis Ritchie. It is also in paragraph 7.5 "Space Efficiency" of "The Practice of Programming" by Brian W. Kernighan and Rob Pike. – Alessandro Jacopson Jul 22 '11 at 6:57
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    This approach cannot create a mask including the top-most bit of the longest unsigned integer type, i.e., usually indicated with a warning like integer overflow in preprocessor expression. – user246672 Oct 8 '15 at 2:35
29

So, you are asking for m set bits prefixed by k reset bits and followed by n reset bits? We can ignore k since it will largely be constrained by the choice of integer type.

mask = ((1 << m) - 1) << n;
13
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    They both work but I find Jonathan's answer to be simpler and clearer. Darius' answer is a little too backwards to me. – Robert Gamble Nov 25 '08 at 6:34
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    Robert, I like the ~0 idiom for bitmasks because it doesn't depend on 2's-complement, and is in that sense simpler, but it's true it's less well-known. Just doing my bit to change that! – Darius Bacon Nov 25 '08 at 7:10
  • @Darius: if you are using unsigned arithmetic/types, as you should in these contexts, isn't the difference between 2's-complement, 1's-complement and sign-magnitude arithmetic immaterial? – Jonathan Leffler Nov 25 '08 at 7:18
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    @Darius, you shouldn't be performing bitwise arithmetic on signed types in the first place and if you were, your solution invokes undefined behavior every time! – Robert Gamble Nov 25 '08 at 7:20
  • Is it undefined? I dont have spec at hand, but I think it is implementation defined, i.e. the compiler is allowed to do it like he wants, but he must always do it the same way. So when you know the treatment (of your compiler) you can rely on it. – flolo Nov 25 '08 at 7:52
5

I like both solutions. Here is another way that comes to my mind (probably not better).

((~((unsigned int)0) << k) >> (k + n)) << n

EDIT: There was a bug in my previous version (it was without the unsigned int cast). The problem was that ~0 >> n adds 1s at the front and not 0s.

And yes this approach has one big downside; it assumes that you know the number of bits of the default integer type or in other words it assumes that you really know k, whereas the other solutions are independent of k. This makes my version less portable, or at least harder to port. (It also uses 3 shifts, and addition and a bitwise negation operator, which is two extra operations.)

So you would do better to use one of the other examples.

Here is a little test app, done by Jonathan Leffler, to compare and verify the output of the different solutions:

#include <stdio.h>
#include <limits.h>

enum { ULONG_BITS = (sizeof(unsigned long) * CHAR_BIT) };

static unsigned long set_mask_1(int k, int m, int n)
{
    return ~(~0 << m) << n;
}

static unsigned long set_mask_2(int k, int m, int n)
{
    return ((1 << m) - 1) << n;
}

static unsigned long set_mask_3(int k, int m, int n)
{
    return ((~((unsigned long)0) << k) >> (k + n)) << n;
}

static int test_cases[][2] =
{
    { 1, 0 },
    { 1, 1 },
    { 1, 2 },
    { 1, 3 },
    { 2, 1 },
    { 2, 2 },
    { 2, 3 },
    { 3, 4 },
    { 3, 5 },
};

int main(void)
{
    size_t i;
    for (i = 0; i < 9; i++)
    {
        int m = test_cases[i][0];
        int n = test_cases[i][1];
        int k = ULONG_BITS - (m + n);
        printf("%d/%d/%d = 0x%08lX = 0x%08lX = 0x%08lX\n", k, m, n,
               set_mask_1(k, m, n),
               set_mask_2(k, m, n),
               set_mask_3(k, m, n));
    }
    return 0;
}
6
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    On the assumption that this answer can be made to work, the obvious downside in comparison with the other two is the presence of the third shift operation, which makes it more time consuming. – Jonathan Leffler Nov 25 '08 at 14:45
  • The other problem is that it uses the parameter k which the other two solutions are able to ignore (it doesn't use m, though, so it still only uses two of the three parameters). – Jonathan Leffler Nov 25 '08 at 14:46
  • Right there was a bug in it, I fixed it now and add a comment that the other solutions are preferable. I haven't removed it completely, maybe someone can learn from my mistakes and it'd be sad to loose your nice test code :). – quinmars Nov 25 '08 at 19:34
  • Instead of the cast, you should be able to use '0U' to indicate an unsigned zero, or '0UL' to indicate an unsigned long. I agree with leaving your answer in place - and with the edits you made. – Jonathan Leffler Nov 25 '08 at 21:06
  • Make this a macro or inline function, the compiler will generate a constant at compile-time instead of code. – user246672 Oct 8 '15 at 2:48
1

(Only) For those who are interested in a slightly more efficient solution on x86 systems with BMI2 support (Intel Haswell or newer, AMD Excavator or newer):

mask = _bzhi_u32(-1,m)<<n;

The bzhi instruction zeros the high bits starting with specified bit position. The _bzhi_u32 intrinsic compiles to this instruction. Test code:

#include <stdio.h>
#include <x86intrin.h>
/*  gcc -O3 -Wall -m64 -march=haswell bitmsk_mn.c   */

unsigned int bitmsk(unsigned int m, unsigned int n)
{
    return _bzhi_u32(-1,m)<<n;
}

int main() {
    int k = bitmsk(7,13);
    printf("k= %08X\n",k);
    return 0;
}

Output:

$./a.out
k= 000FE000

The code fragment _bzhi_u32(-1,m)<<n compiles to three instructions

movl    $-1, %edx
bzhi    %edi, %edx, %edi
shlx    %esi, %edi, %eax

Which is one instruction less than the codes by @Jonathan Leffler and @Darius Bacon. On Intel Haswell processors or newer, both bzhi and shlx have a latency of 1 cycle and a throughput of 2 per cycle. On AMD Ryzen these two instructions even have a throughput of 4 per cycle.

0

Whilst the top answers are simple and effective they don't set the MSB for the case when n=0 and m=31:

~(~0 << 31) << 0 = ‭0111 1111 1111 1111 1111 1111 1111 1111‬

((1 << 31)-1) << 0 = ‭0111 1111 1111 1111 1111 1111 1111 1111‬

My suggestion for a 32-bit unsigned word (which is ugly and has a branch) looks like this:

unsigned int create_mask(unsigned int n,unsigned int m) {
  // 0 <= start_bit, end_bit <= 31
  return (m - n == 31 ? 0xFFFFFFFF : ((1 << (m-n)+1)-1) << n);
}

This actually gets the bits in the range [m,n] (closed interval) so create_mask(0,0) will return a mask for the first bit (bit 0) and create_mask(4,6) returns a mask for bits 4 to 6 i.e ... 00111 0000.

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