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I was facing this unique problem of generating a bit-mask based on the input parameter. For example,

if param = 2, then the mask will be 0x3 (11b) if param = 5, then the mask will be 0x1F (1 1111b)

This I implemented using a for-loop in C, something like

int nMask = 0;
for (int i = 0; i < param; i ++) {

    nMask |= (1 << i);
}

I would like to know if there is a better algorithm ~~~

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Going by your description, this would probably be the simplest you could do.. pending any inbuilt stuff :p –  glasnt Sep 8 '09 at 5:01

4 Answers 4

up vote 23 down vote accepted

One thing to notice about bitmasks like that is that they are always one less than a power of two.

The expression "1 << n" is the easy way to get the n-th power of two.

You don't want Zero to provide a bitmask of "00000001", you want it to provide zero. So you need to subtract one.

mask = (1 << param) - 1;

Edit:

If you want a special case for param > 32:

int sizeInBits = sizeof(mask) * BITS_PER_BYTE; // BITS_PER_BYTE = 8;
mask = (param >= sizeInBits ? -1 : (1 <<  param) - 1);

This method should work for 16, 32, or 64 bit integers, but you may have to explicitly type the '1'.

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2  
Nice idea, subtracting to get all ones :) –  AraK Sep 8 '09 at 5:06
    
Thanks. I figured it out when I was building binary trees for a single elimination bracket. –  John Gietzen Sep 8 '09 at 5:07
4  
This is the canonical solution, with two caveats. First, you should probably be using unsigned int for mask and 1U as the left side of the shift operator, and secondly be aware that the result is unspecified if param is equal or greater than the number of bits in int (or one less than the number of bits, if you continue to use signed math). If this is a problem in your environment, use a lookup table instead. –  caf Sep 8 '09 at 5:33
1  
Also, while the C++ standard strictly says that the case param == width_of_unsigned_in_bits produces Undefined Behaviour for left-shift, it would be very surprising to meet an implementation that did not just produce the value 0 in this case. So in practice I wouldn't actually bother with the special case if, since the mainline code handles it fine. –  j_random_hacker Sep 9 '09 at 4:17
2  
Have you actually tested it? On my x86, under gcc, it produces zero as the mask for param = 32, not all-ones (because the x86 shift actually shifts by param modulo 32). I don't think the lookup table would be significantly slower in most cases. –  caf Sep 10 '09 at 2:02

For those interested, this is the lookup-table alternative discussed in comments to the other answer - the difference being that it works correctly for a param of 32. It's easy enough to extend to the 64 bit unsigned long long version, if you need that, and shouldn't be significantly different in speed (if it's called in a tight inner loop then the static table will stay in at least L2 cache, and if it's not called in a tight inner loop then the performance difference won't be important).

unsigned long mask2(unsigned param)
{
    static const unsigned long masks[] = {
        0x00000000UL, 0x00000001UL, 0x00000003UL, 0x00000007UL,
        0x0000000fUL, 0x0000001fUL, 0x0000003fUL, 0x0000007fUL,
        0x000000ffUL, 0x000001ffUL, 0x000003ffUL, 0x000007ffUL,
        0x00000fffUL, 0x00001fffUL, 0x00003fffUL, 0x00007fffUL,
        0x0000ffffUL, 0x0001ffffUL, 0x0003ffffUL, 0x0007ffffUL,
        0x000fffffUL, 0x001fffffUL, 0x003fffffUL, 0x007fffffUL,
        0x00ffffffUL, 0x01ffffffUL, 0x03ffffffUL, 0x07ffffffUL,
        0x0fffffffUL, 0x1fffffffUL, 0x3fffffffUL, 0x7fffffffUL,
        0xffffffffUL };

    if (param < (sizeof masks / sizeof masks[0]))
        return masks[param];
    else
        return 0xffffffffUL; /* Or whatever else you want to do in this error case */
}

It's worth pointing out that if you need the if() statement (because are worried that someone might call it with param > 32), then this doesn't win you anything over the alternative from the other answer:

unsigned long mask(unsigned param)
{
    if (param < 32)
        return (1UL << param) - 1;
    else
        return -1;
}

The only difference is that the latter version has to special case param >= 32, whereas the former only has to special case param > 32.

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Alternatively, you can use a right shift to avoid the issue mentioned in the (1 << param) - 1 solution.

unsigned long const mask = 0xffffffffUL >> (32 - param);

assuming that param <= 32, of course.

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Efficient, Branch-Free, Portable and Generic (but Ugly) Implementation

C:

#include <limits.h>     /* CHAR_BIT */

#define BIT_MASK(__TYPE__, __ONE_COUNT__) \
    ((__TYPE__) (-((__ONE_COUNT__) != 0))) \
    & (((__TYPE__) -1) >> ((sizeof(__TYPE__) * CHAR_BIT) - (__ONE_COUNT__)))

C++:

#include <climits>

template <typename R>
static constexpr R bitmask(unsigned int const onecount)
{
//  return (onecount != 0)
//      ? (static_cast<R>(-1) >> ((sizeof(R) * CHAR_BIT) - onecount))
//      : 0;
    return static_cast<R>(-(onecount != 0))
        & (static_cast<R>(-1) >> ((sizeof(R) * CHAR_BIT) - onecount));
}

Usage (Producing Compile Time Constants)

BIT_MASK(unsigned int, 4) /* = 0x0000000f */

BIT_MASK(uint64_t, 26) /* = 0x0000000003ffffffULL */

Example

#include <stdio.h>

int main()
{
    unsigned int param;
    for (param = 0; param <= 32; ++param)
    {
        printf("%u => 0x%08x\n", param, BIT_MASK(unsigned int, param));
    }
    return 0;
}

Output

0 => 0x00000000
1 => 0x00000001
2 => 0x00000003
3 => 0x00000007
4 => 0x0000000f
5 => 0x0000001f
6 => 0x0000003f
7 => 0x0000007f
8 => 0x000000ff
9 => 0x000001ff
10 => 0x000003ff
11 => 0x000007ff
12 => 0x00000fff
13 => 0x00001fff
14 => 0x00003fff
15 => 0x00007fff
16 => 0x0000ffff
17 => 0x0001ffff
18 => 0x0003ffff
19 => 0x0007ffff
20 => 0x000fffff
21 => 0x001fffff
22 => 0x003fffff
23 => 0x007fffff
24 => 0x00ffffff
25 => 0x01ffffff
26 => 0x03ffffff
27 => 0x07ffffff
28 => 0x0fffffff
29 => 0x1fffffff
30 => 0x3fffffff
31 => 0x7fffffff
32 => 0xffffffff

Explanation

First of all, as already discussed in other answers, >> is used instead of << in order to prevent the problem when the shift count is equal to the number of bits of the storage type of the value. (Thanks Julien's answer above for the idea)

For the ease of discussion, let's "instantiate" the macro with unsigned int as __TYPE__ and see what happens (assuming 32-bit for the moment):

((unsigned int) (-((__ONE_COUNT__) != 0))) \
& (((unsigned int) -1) >> ((sizeof(unsigned int) * CHAR_BIT) - (__ONE_COUNT__)))

Let's focus on:

((sizeof(unsigned int) * CHAR_BIT)

first. sizeof(unsigned int) is known at compile time. It is equal to 4 according to our assumption. CHAR_BIT represents the number of bits per char, a.k.a. per byte. It is also known at compile time. It is equal to 8 on most machines on the Earth. Since this expression is known at a compile time, the compiler would probably do the multiplication at compile time and treat it as a constant, which equals to 32 in this case.

Let's move to:

((unsigned int) -1)

It is equal to 0xFFFFFFFF. Casting -1 to any unsigned type produces a value of "all-1s" in that type. This part is also a compile time constant.

Up to now, the expression:

(((unsigned int) -1) >> ((sizeof(unsigned int) * CHAR_BIT) - (__ONE_COUNT__)))

is in fact the same as:

0xffffffffUL >> (32 - param)

which is the same as Julien's answer above. One problem with his answer is that if param is equal to 0, producing the expression 0xffffffffUL >> 32, the result of the expression would be 0xffffffffUL, instead of the expected 0! (That's why I name my parameter as __ONE_COUNT__ to emphasize its intention)

To solve this problem, we could simply add a special case for __ONE_COUNT equals 0 using if-else or ?:, like this:

#define BIT_MASK(__TYPE__, __ONE_COUNT__) \
    (((__ONE_COUNT__) != 0) \
    ? (((__TYPE__) -1) >> ((sizeof(__TYPE__) * CHAR_BIT) - (__ONE_COUNT__)))
    : 0)

But branch-free code is cooler, isn't it?! Let's move to the next part:

((unsigned int) (-((__ONE_COUNT__) != 0)))

Let's start from the innermost expression to the outermost. ((__ONE_COUNT__) != 0) produces 0 when the parameter is 0, or 1 otherwise. (-((__ONE_COUNT__) != 0)) produces 0 when the parameter is 0, or -1 otherwise. For ((unsigned int) (-((__ONE_COUNT__) != 0))), the type-cast trick ((unsigned int) -1) is already explained above. Do you notice the trick now? The expression:

((__TYPE__) (-((__ONE_COUNT__) != 0)))

equals to "all-0s" if __ONE_COUNT__ is zero, and "all-1s" otherwise. It acts as a bit-mask for the value we calculated in the first step. So, if __ONE_COUNT__ is non-zero, the mask as no effect and it is the same as Julien's answer. If __ONE_COUNT__ is 0, it mask away all bits of Julien's answer, producing a constant zero. To visualize, watch this:

__ONE_COUNT__ :                           0                Other
                                          -------------    --------------
(__ONE_COUNT__)                           0 = 0x000...0    (itself)
((__ONE_COUNT__) != 0)                    0 = 0x000...0     1 = 0x000...1
((__TYPE__) (-((__ONE_COUNT__) != 0)))    0 = 0x000...0    -1 = 0xFFF...F
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